--- http_interactions: - request: method: post uri: https://standards.ieee.org/wp-admin/admin-ajax.php body: encoding: UTF-8 string: action=ieee_cloudsearch&q=IEEE+528-2019 headers: User-Agent: - Faraday v1.10.0 Content-Type: - application/x-www-form-urlencoded Accept-Encoding: - gzip;q=1.0,deflate;q=0.6,identity;q=0.3 Accept: - "*/*" response: status: code: 200 message: OK headers: Date: - Thu, 30 Jun 2022 17:16:18 GMT Content-Type: - text/html; charset=UTF-8 Transfer-Encoding: - chunked Connection: - keep-alive X-Robots-Tag: - noindex X-Content-Type-Options: - nosniff Expires: - Wed, 11 Jan 1984 05:00:00 GMT Cache-Control: - no-cache, must-revalidate, max-age=0 Referrer-Policy: - strict-origin-when-cross-origin X-Frame-Options: - SAMEORIGIN Vary: - Accept-Encoding X-Powered-By: - WP Engine Cf-Cache-Status: - DYNAMIC Expect-Ct: - max-age=604800, report-uri="https://report-uri.cloudflare.com/cdn-cgi/beacon/expect-ct" Server: - cloudflare Cf-Ray: - 72388c83b9460f9a-VIE Alt-Svc: - h3=":443"; ma=86400, h3-29=":443"; ma=86400 body: encoding: ASCII-8BIT string: '{"status":"ok","total_pages":3,"results":{"status":{"rid":"w6H0rJsw51sK1E5c","time-ms":9},"hits":{"found":27,"start":0,"hit":[{"id":"c1dc1ae6ae407ec0a8a761c1e4e0832655dda6ed376d509c9f6f5cd99767c79abf416c615774db732cc8100d9c5a2eb0cfa7709ce0d82b88b603bbaba6278fd0","fields":{"doc_id_l":"https:\/\/standards.ieee.org\/ieee\/528\/7292\/","doc_text_t":"IEEE SA - IEEE 528-2019 IEEE.org IEEE Xplore Digital Library IEEE Standards IEEE Spectrum More Sites eTools Standards Access Standards Search Standards Standards Development Standards Adoption Products & Programs Alliance Management Services Conformity Assessment & Certification IEEE SA Open Source Industry Affiliate Network (IAN) Industry Connections The National Electrical Safety Code\u00ae (NESC\u00ae) Registration Authority Government Engagement Program on Standards (GEPS) Standards Fellowship All Products & Programs Focuses Artificial Intelligence Systems (AIS) Connectivity & Telecom Energy Foundational Technologies Healthcare and Life Sciences Mobility Government Engagement Get Involved Events IEEE SA Membership How to Get Involved Resources Training & Development News IEEE SA Newsletter Standards Store MAC ADDRESS Active Standard IEEE 528-2019 IEEE Standard for Inertial Sensor Terminology Purchase Access via Subscription Home Standards IEEE 528-2019 Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Status Active Standard PAR Approval 2018-05-14 Superseding 528-2001 Board Approval 2019-06-13 History Published: 2019-10-08 Working Group Details Society IEEE Aerospace and Electronic Systems Society Learn More Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Working Group SENSR_WG - Sensors Working Group Learn More IEEE Program Manager Soo Kim Contact Working Group Chair Harry Davis Active Projects Active Standards Superseded Standards Inactive-Withdrawn Standards Inactive-Reserved Standards P1431 Standard for Specifying and Testing Coriolis Vibratory Gyros This standard defines requirements and test procedures for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1293-2018 IEEE Standard Specification Format Guide and Test Procedure for Linear Single-Axis, Nongyroscopic Accelerometers The specification and test requirements for a linear, single-axis, nongyroscopic accelerometer for use in inertial navigation, guidance, and leveling systems are defined. A standard specification guide and a compilation of recommended test procedures for such accelerometers are provided. Informative annexes are given on the various types of such accelerometers (force or pendulous torque rebalance with analog or digital output, vibrating beam, and micromechanical) and error effects, on filtering, noise, and transient analysis techniques, and on calibration and modeling techniques (multipoint tumble analysis, vibration and shock test analyses, and geophysical effects in inertial instrument testing). Learn More 952-2020 IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently used in the industry. Learn More 1293-1998\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Linear,Single-Axis, Nongyroscopic Accelerometers Corrigendum 1: Changes to Annex K and Annex L Corrigendum to IEEE Std 1293-1998. Specification and test requirements for linear, single-axis, nongyroscopic accelerometers for use as a sensor in attitude control systems, linear displacement measuring systems, and linear rate measuring systems are defined. The specification format guide and test procedure standard applies to force-rebalance accelerometers (pendulous or translational proof mass), vibrating beam accelerometers (VBAs), and micromechanical accelerometers that range from lesser accuracy to high accuracy devices. Learn More 528-2001 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-1997 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros Specification and test requirements for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis IFOG is provided. A compilation of recommended procedures for testing a fiber optic gyro, derived from those presently used in the industry, is also provided. Learn More 952-1997\/Cor 1-2016 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros -- Corrigendum 1: Figure 1 and Subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1 Errors identified in IEEE Std 952-1997 are corrected in this corrigendum. Corrections are made to Figure 1 and in subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1. Learn More No Inactive-Withdrawn Standards 1431-2004 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros Specification and test requirements for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A stadard specification format guide for the preparation of a single-axis CVG is provided. A complilation of recommended procedures for testing a CVG, derived from those presently used in the industry, is also provided. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1431-2004\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros - Corrigendum 1 Corrigendum to IEEE Std 1431-2004. Learn More 1554-2005 IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice. Learn More 292-1969 IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch closure(s) at angular rates (exceeding,less than)______ (+,-,u00b1)______ degrees per second]. Learn More 293-1969 IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide in the preparation of Section 4 of a specification that follows the format of IEEE Std 292, Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros. Learn More 293-1969\/Cor 1-2014 IEEE Standard for IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros -- Corrigendum 1: Table 1 Heading Correction to Table 1 on page 14 of IEEE Std 293-1969 Learn More 517-1974 IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given. Learn More 529-1980 Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyroscope specification is presented. Recommended procedures for testing a rate-integrating gyroscope are compiled. This standard, when combined with IEEE Std 517-1974 (R1980), defines the requirements and test procedures in terms of characteristics unique to the gyroscope or those applications in which the dynamic angular inputs are significantly greater than the limitations identified in IEEE Std 517. Learn More 529-1980\/Cor 1-2017 IEEE Standard Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros - Corrigendum 1: 3.3.9.2.2, 3.6.4.1.1, 3.6.4.1.2, 6.3, and 10.10.4.1 Corrections are made by this corrigendum to material already published in IEEE Std 529-1980. Learn More 647-2006 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Laser Gyros Specification and test requirements for a single-axis ring laser gyro (RLG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis RLG is provided. A compilation of recommended procedures for testing an RLG, derived from those presently used in the industry, is also provided. Learn More 671-1985 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been developed to meet needs not easily met by traditional spinning-rotor gyroscopes. A test procedure for verifying that the specifications have been met is given. The standard is not intended to compete with existing standards for specific devices with highly specific models and error sources, such as spring-restrained rate gyros, but to provide a uniform guide for those inertial angular sensors that have not been covered elsewhere. Learn More 671-1985\/Cor 1-2010 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement Corrigendum 1: 4.7.2.6 Short-Term Stability and Annex A Sensor Dynamic Block Diagrams IEEE Std 671-1985 provides specifications and test requirements for a non-gyroscopic inertial angular sensor that may measure angular jerk, acceleration, rate, or displacement with or without response down to zero frequency. A standard specification format is provided. A compilation of recommended test procedures, derived from those presently used in the industry, is also provided. Informative annexes cover design features and theoretical principles of operation. This corrigendum makes changes to 4.7.2.6 to delete a sentence that does not belong there, to add a subclause that was inadvertently left out, and to renumber the existing subclauses. Changes are also being made to fix the block diagrams in Annex A, to correct a misspelling of inertia, and to add a missing symbol. Learn More 813-1988 IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also given. The requirements and test procedures are defined in terms unique to the DTG. They cover applications of the gyro as an angular motion sensor in navigation and control systems. They apply to two modes of use: (1) as a strap-down sensor in operating environments typical of aircraft and missile applications, and (2) as a sensor in gimballed platform applications in which the dynamic angular inputs to which the gyro is subjected are benign relative to the accuracy required. In the case of the strap-down DTG, the characteristics of the external capture loops are considered to the extent necessary to define the gyro performance. Learn More 836-2009 IEEE Recommended Practice for Precision Centrifuge Testing of Linear Accelerometers This recommended practice describes the conduct and analysis of precision tests that are to be performed on linear accelerometers using centrifuge techniques. The term u201cprecision,u201d in this context, refers to tests that are conducted to evaluate accelerometer parameters, as opposed to those conducted to establish environmental survivability only. Evaluation may take the form of determining the coefficients of the accelerometer''s model equation, except for bias and scale factor, which are most accurately determined by static multi-position tests. Alternatively, evaluation may only establish that the accelerometer output complies with specific error limit criteria. 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A not-for-profit organization, IEEE is the world\u2019s largest technical professional organization dedicated to advancing technology for the benefit of humanity. Subscribe Newswire Sign up for our monthly newsletter to learn about new developments, including resources, insights and more. ","doc_title_t":"IEEE SA - IEEE 528-2019","doc_type_l":"text\/html","meta_description_l":"Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology.","meta_designation_l":"IEEE 528-2019","meta_keywords_la":["Aerospace Electronics"],"meta_title_t":"IEEE SA - IEEE Standard for Inertial Sensor Terminology","meta_topic_la":["Aerospace Electronics"],"meta_type_la":["Standard"]}},{"id":"9cbcfe1a1a10411b11c4725a58de46093d36dbb24df9cf54f22fc40c487274be111ebd55c6bbfdced6a400f258cc88df638efa40720209c344f3f919968e9a7b","fields":{"doc_id_l":"https:\/\/standards.ieee.org\/ieee\/528\/780\/","doc_text_t":"IEEE SA - IEEE 528-2001 IEEE.org IEEE Xplore Digital Library IEEE Standards IEEE Spectrum More Sites eTools Standards Access Standards Search Standards Standards Development Standards Adoption Products & Programs Alliance Management Services Conformity Assessment & Certification IEEE SA Open Source Industry Affiliate Network (IAN) Industry Connections The National Electrical Safety Code\u00ae (NESC\u00ae) Registration Authority Government Engagement Program on Standards (GEPS) Standards Fellowship All Products & Programs Focuses Artificial Intelligence Systems (AIS) Connectivity & Telecom Energy Foundational Technologies Healthcare and Life Sciences Mobility Government Engagement Get Involved Events IEEE SA Membership How to Get Involved Resources Training & Development News IEEE SA Newsletter Standards Store MAC ADDRESS Superseded Standard IEEE 528-2001 IEEE Standard for Inertial Sensor Terminology Purchase Access via Subscription Home Standards IEEE 528-2001 Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Status Superseded Standard PAR Approval 1998-12-08 Superseded by 528-2019 Superseding 528-1994 Board Approval 2001-08-07 History ANSI Approved: 2002-01-02 Published: 2001-11-29 Reaffirmed: 2007-03-22 Working Group Details Society IEEE Aerospace and Electronic Systems Society Learn More Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Working Group SENSR_WG - Sensors Working Group Learn More IEEE Program Manager Soo Kim Contact Working Group Chair Harry Davis Active Projects Active Standards Superseded Standards Inactive-Withdrawn Standards Inactive-Reserved Standards P1431 Standard for Specifying and Testing Coriolis Vibratory Gyros This standard defines requirements and test procedures for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1293-2018 IEEE Standard Specification Format Guide and Test Procedure for Linear Single-Axis, Nongyroscopic Accelerometers The specification and test requirements for a linear, single-axis, nongyroscopic accelerometer for use in inertial navigation, guidance, and leveling systems are defined. A standard specification guide and a compilation of recommended test procedures for such accelerometers are provided. Informative annexes are given on the various types of such accelerometers (force or pendulous torque rebalance with analog or digital output, vibrating beam, and micromechanical) and error effects, on filtering, noise, and transient analysis techniques, and on calibration and modeling techniques (multipoint tumble analysis, vibration and shock test analyses, and geophysical effects in inertial instrument testing). Learn More 528-2019 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-2020 IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently used in the industry. Learn More 1293-1998\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Linear,Single-Axis, Nongyroscopic Accelerometers Corrigendum 1: Changes to Annex K and Annex L Corrigendum to IEEE Std 1293-1998. Specification and test requirements for linear, single-axis, nongyroscopic accelerometers for use as a sensor in attitude control systems, linear displacement measuring systems, and linear rate measuring systems are defined. The specification format guide and test procedure standard applies to force-rebalance accelerometers (pendulous or translational proof mass), vibrating beam accelerometers (VBAs), and micromechanical accelerometers that range from lesser accuracy to high accuracy devices. Learn More 952-1997 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros Specification and test requirements for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis IFOG is provided. A compilation of recommended procedures for testing a fiber optic gyro, derived from those presently used in the industry, is also provided. Learn More 952-1997\/Cor 1-2016 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros -- Corrigendum 1: Figure 1 and Subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1 Errors identified in IEEE Std 952-1997 are corrected in this corrigendum. Corrections are made to Figure 1 and in subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1. Learn More No Inactive-Withdrawn Standards 1431-2004 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros Specification and test requirements for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A stadard specification format guide for the preparation of a single-axis CVG is provided. A complilation of recommended procedures for testing a CVG, derived from those presently used in the industry, is also provided. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1431-2004\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros - Corrigendum 1 Corrigendum to IEEE Std 1431-2004. Learn More 1554-2005 IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice. Learn More 292-1969 IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch closure(s) at angular rates (exceeding,less than)______ (+,-,u00b1)______ degrees per second]. Learn More 293-1969 IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide in the preparation of Section 4 of a specification that follows the format of IEEE Std 292, Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros. Learn More 293-1969\/Cor 1-2014 IEEE Standard for IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros -- Corrigendum 1: Table 1 Heading Correction to Table 1 on page 14 of IEEE Std 293-1969 Learn More 517-1974 IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given. Learn More 529-1980 Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyroscope specification is presented. Recommended procedures for testing a rate-integrating gyroscope are compiled. This standard, when combined with IEEE Std 517-1974 (R1980), defines the requirements and test procedures in terms of characteristics unique to the gyroscope or those applications in which the dynamic angular inputs are significantly greater than the limitations identified in IEEE Std 517. Learn More 529-1980\/Cor 1-2017 IEEE Standard Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros - Corrigendum 1: 3.3.9.2.2, 3.6.4.1.1, 3.6.4.1.2, 6.3, and 10.10.4.1 Corrections are made by this corrigendum to material already published in IEEE Std 529-1980. Learn More 647-2006 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Laser Gyros Specification and test requirements for a single-axis ring laser gyro (RLG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis RLG is provided. A compilation of recommended procedures for testing an RLG, derived from those presently used in the industry, is also provided. Learn More 671-1985 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been developed to meet needs not easily met by traditional spinning-rotor gyroscopes. A test procedure for verifying that the specifications have been met is given. The standard is not intended to compete with existing standards for specific devices with highly specific models and error sources, such as spring-restrained rate gyros, but to provide a uniform guide for those inertial angular sensors that have not been covered elsewhere. Learn More 671-1985\/Cor 1-2010 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement Corrigendum 1: 4.7.2.6 Short-Term Stability and Annex A Sensor Dynamic Block Diagrams IEEE Std 671-1985 provides specifications and test requirements for a non-gyroscopic inertial angular sensor that may measure angular jerk, acceleration, rate, or displacement with or without response down to zero frequency. A standard specification format is provided. A compilation of recommended test procedures, derived from those presently used in the industry, is also provided. Informative annexes cover design features and theoretical principles of operation. This corrigendum makes changes to 4.7.2.6 to delete a sentence that does not belong there, to add a subclause that was inadvertently left out, and to renumber the existing subclauses. Changes are also being made to fix the block diagrams in Annex A, to correct a misspelling of inertia, and to add a missing symbol. Learn More 813-1988 IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also given. The requirements and test procedures are defined in terms unique to the DTG. They cover applications of the gyro as an angular motion sensor in navigation and control systems. They apply to two modes of use: (1) as a strap-down sensor in operating environments typical of aircraft and missile applications, and (2) as a sensor in gimballed platform applications in which the dynamic angular inputs to which the gyro is subjected are benign relative to the accuracy required. In the case of the strap-down DTG, the characteristics of the external capture loops are considered to the extent necessary to define the gyro performance. Learn More 836-2009 IEEE Recommended Practice for Precision Centrifuge Testing of Linear Accelerometers This recommended practice describes the conduct and analysis of precision tests that are to be performed on linear accelerometers using centrifuge techniques. The term u201cprecision,u201d in this context, refers to tests that are conducted to evaluate accelerometer parameters, as opposed to those conducted to establish environmental survivability only. Evaluation may take the form of determining the coefficients of the accelerometer''s model equation, except for bias and scale factor, which are most accurately determined by static multi-position tests. Alternatively, evaluation may only establish that the accelerometer output complies with specific error limit criteria. Learn More Facebook Twitter LinkedIn Instagram YouTube IEEE SA About Us IEEE SA Membership Entity Program Distributor Program Training & Development Policies & Procedures Contact Us Board of Governors About Board of Governors Awards Committee Corporate Advisory Group Industry Connections Committee Registration Authority Committee Strategic Planning Coordination Committee Standards Board About Standards Board Board Approvals Audit Committee New Standards Committee Patent Committee Procedures Committee Standards Review Committee News & Events News IEEE SA Newsletter Events Home Sitemap Contact & Support Accessibility Nondiscrimination Policy IEEE Ethics Reporting IEEE Privacy Policy IEEE SA Copyright Policy \u00a9 Copyright 2021 IEEE \u2013 All rights reserved. Use of this website signifies your agreement to the IEEE Terms and Conditions . A not-for-profit organization, IEEE is the world\u2019s largest technical professional organization dedicated to advancing technology for the benefit of humanity. Subscribe Newswire Sign up for our monthly newsletter to learn about new developments, including resources, insights and more. ","doc_title_t":"IEEE SA - IEEE 528-2001","doc_type_l":"text\/html","meta_description_l":"Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology.","meta_designation_l":"IEEE 528-2001","meta_keywords_la":["Aerospace Electronics,Power and Energy"],"meta_title_t":"IEEE SA - IEEE Standard for Inertial Sensor Terminology","meta_topic_la":["Aerospace Electronics,Power and Energy"],"meta_type_la":["Standard"]}},{"id":"1e7fa450951b3af061c01809cb2a2b51676250c0d1331c7347e03c5433bf478168f717fe2f8de898a11955cc575ef729baee3a2c2e1be936f000d19dcd689a81","fields":{"doc_id_l":"https:\/\/standards.ieee.org\/ieee\/952\/7496\/","doc_text_t":"IEEE SA - IEEE 952-2020 IEEE.org IEEE Xplore Digital Library IEEE Standards IEEE Spectrum More Sites eTools Standards Access Standards Search Standards Standards Development Standards Adoption Products & Programs Alliance Management Services Conformity Assessment & Certification IEEE SA Open Source Industry Affiliate Network (IAN) Industry Connections The National Electrical Safety Code\u00ae (NESC\u00ae) Registration Authority Government Engagement Program on Standards (GEPS) Standards Fellowship All Products & Programs Focuses Artificial Intelligence Systems (AIS) Connectivity & Telecom Energy Foundational Technologies Healthcare and Life Sciences Mobility Government Engagement Get Involved Events IEEE SA Membership How to Get Involved Resources Training & Development News IEEE SA Newsletter Standards Store MAC ADDRESS Active Standard IEEE 952-2020 IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros Purchase Access via Subscription Home Standards IEEE 952-2020 Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently used in the industry. Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Status Active Standard PAR Approval 2019-02-08 Superseding 952-1997 Board Approval 2020-09-24 History Published: 2021-02-12 Working Group Details Society IEEE Aerospace and Electronic Systems Society Learn More Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Working Group SENSR_WG - Sensors Working Group Learn More IEEE Program Manager Soo Kim Contact Working Group Chair Harry Davis Active Projects Active Standards Superseded Standards Inactive-Withdrawn Standards Inactive-Reserved Standards P1431 Standard for Specifying and Testing Coriolis Vibratory Gyros This standard defines requirements and test procedures for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1293-2018 IEEE Standard Specification Format Guide and Test Procedure for Linear Single-Axis, Nongyroscopic Accelerometers The specification and test requirements for a linear, single-axis, nongyroscopic accelerometer for use in inertial navigation, guidance, and leveling systems are defined. A standard specification guide and a compilation of recommended test procedures for such accelerometers are provided. Informative annexes are given on the various types of such accelerometers (force or pendulous torque rebalance with analog or digital output, vibrating beam, and micromechanical) and error effects, on filtering, noise, and transient analysis techniques, and on calibration and modeling techniques (multipoint tumble analysis, vibration and shock test analyses, and geophysical effects in inertial instrument testing). Learn More 528-2019 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 1293-1998\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Linear,Single-Axis, Nongyroscopic Accelerometers Corrigendum 1: Changes to Annex K and Annex L Corrigendum to IEEE Std 1293-1998. Specification and test requirements for linear, single-axis, nongyroscopic accelerometers for use as a sensor in attitude control systems, linear displacement measuring systems, and linear rate measuring systems are defined. The specification format guide and test procedure standard applies to force-rebalance accelerometers (pendulous or translational proof mass), vibrating beam accelerometers (VBAs), and micromechanical accelerometers that range from lesser accuracy to high accuracy devices. Learn More 528-2001 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-1997 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros Specification and test requirements for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis IFOG is provided. A compilation of recommended procedures for testing a fiber optic gyro, derived from those presently used in the industry, is also provided. Learn More 952-1997\/Cor 1-2016 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros -- Corrigendum 1: Figure 1 and Subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1 Errors identified in IEEE Std 952-1997 are corrected in this corrigendum. Corrections are made to Figure 1 and in subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1. Learn More No Inactive-Withdrawn Standards 1431-2004 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros Specification and test requirements for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A stadard specification format guide for the preparation of a single-axis CVG is provided. A complilation of recommended procedures for testing a CVG, derived from those presently used in the industry, is also provided. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1431-2004\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros - Corrigendum 1 Corrigendum to IEEE Std 1431-2004. Learn More 1554-2005 IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice. Learn More 292-1969 IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch closure(s) at angular rates (exceeding,less than)______ (+,-,u00b1)______ degrees per second]. Learn More 293-1969 IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide in the preparation of Section 4 of a specification that follows the format of IEEE Std 292, Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros. Learn More 293-1969\/Cor 1-2014 IEEE Standard for IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros -- Corrigendum 1: Table 1 Heading Correction to Table 1 on page 14 of IEEE Std 293-1969 Learn More 517-1974 IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given. Learn More 529-1980 Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyroscope specification is presented. Recommended procedures for testing a rate-integrating gyroscope are compiled. This standard, when combined with IEEE Std 517-1974 (R1980), defines the requirements and test procedures in terms of characteristics unique to the gyroscope or those applications in which the dynamic angular inputs are significantly greater than the limitations identified in IEEE Std 517. Learn More 529-1980\/Cor 1-2017 IEEE Standard Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros - Corrigendum 1: 3.3.9.2.2, 3.6.4.1.1, 3.6.4.1.2, 6.3, and 10.10.4.1 Corrections are made by this corrigendum to material already published in IEEE Std 529-1980. Learn More 647-2006 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Laser Gyros Specification and test requirements for a single-axis ring laser gyro (RLG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis RLG is provided. A compilation of recommended procedures for testing an RLG, derived from those presently used in the industry, is also provided. Learn More 671-1985 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been developed to meet needs not easily met by traditional spinning-rotor gyroscopes. A test procedure for verifying that the specifications have been met is given. The standard is not intended to compete with existing standards for specific devices with highly specific models and error sources, such as spring-restrained rate gyros, but to provide a uniform guide for those inertial angular sensors that have not been covered elsewhere. Learn More 671-1985\/Cor 1-2010 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement Corrigendum 1: 4.7.2.6 Short-Term Stability and Annex A Sensor Dynamic Block Diagrams IEEE Std 671-1985 provides specifications and test requirements for a non-gyroscopic inertial angular sensor that may measure angular jerk, acceleration, rate, or displacement with or without response down to zero frequency. A standard specification format is provided. A compilation of recommended test procedures, derived from those presently used in the industry, is also provided. Informative annexes cover design features and theoretical principles of operation. This corrigendum makes changes to 4.7.2.6 to delete a sentence that does not belong there, to add a subclause that was inadvertently left out, and to renumber the existing subclauses. Changes are also being made to fix the block diagrams in Annex A, to correct a misspelling of inertia, and to add a missing symbol. Learn More 813-1988 IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also given. The requirements and test procedures are defined in terms unique to the DTG. They cover applications of the gyro as an angular motion sensor in navigation and control systems. They apply to two modes of use: (1) as a strap-down sensor in operating environments typical of aircraft and missile applications, and (2) as a sensor in gimballed platform applications in which the dynamic angular inputs to which the gyro is subjected are benign relative to the accuracy required. In the case of the strap-down DTG, the characteristics of the external capture loops are considered to the extent necessary to define the gyro performance. Learn More 836-2009 IEEE Recommended Practice for Precision Centrifuge Testing of Linear Accelerometers This recommended practice describes the conduct and analysis of precision tests that are to be performed on linear accelerometers using centrifuge techniques. The term u201cprecision,u201d in this context, refers to tests that are conducted to evaluate accelerometer parameters, as opposed to those conducted to establish environmental survivability only. Evaluation may take the form of determining the coefficients of the accelerometer''s model equation, except for bias and scale factor, which are most accurately determined by static multi-position tests. Alternatively, evaluation may only establish that the accelerometer output complies with specific error limit criteria. 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A not-for-profit organization, IEEE is the world\u2019s largest technical professional organization dedicated to advancing technology for the benefit of humanity. Subscribe Newswire Sign up for our monthly newsletter to learn about new developments, including resources, insights and more. ","doc_title_t":"IEEE SA - IEEE 952-2020","doc_type_l":"text\/html","meta_description_l":"Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently used in the industry.","meta_designation_l":"IEEE 952-2020","meta_keywords_la":["Aerospace Electronics"],"meta_title_t":"IEEE SA - IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros","meta_topic_la":["Aerospace Electronics"],"meta_type_la":["Standard"]}},{"id":"417d99a37a89b4111b7bc1619f19726d1ab6a092235b6f3f68257dbfc26f55108f71965f44f58344641e674d518e15d40ca211830ab3c8a09cf3212772ab1c67","fields":{"doc_id_l":"https:\/\/standards.ieee.org\/ieee\/671\/926\/","doc_text_t":"IEEE SA - IEEE 671-1985 IEEE.org IEEE Xplore Digital Library IEEE Standards IEEE Spectrum More Sites eTools Standards Access Standards Search Standards Standards Development Standards Adoption Products & Programs Alliance Management Services Conformity Assessment & Certification IEEE SA Open Source Industry Affiliate Network (IAN) Industry Connections The National Electrical Safety Code\u00ae (NESC\u00ae) Registration Authority Government Engagement Program on Standards (GEPS) Standards Fellowship All Products & Programs Focuses Artificial Intelligence Systems (AIS) Connectivity & Telecom Energy Foundational Technologies Healthcare and Life Sciences Mobility Government Engagement Get Involved Events IEEE SA Membership How to Get Involved Resources Training & Development News IEEE SA Newsletter Standards Store MAC ADDRESS Inactive-Reserved Standard IEEE 671-1985 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement Purchase Access via Subscription Home Standards IEEE 671-1985 A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been developed to meet needs not easily met by traditional spinning-rotor gyroscopes. A test procedure for verifying that the specifications have been met is given. The standard is not intended to compete with existing standards for specific devices with highly specific models and error sources, such as spring-restrained rate gyros, but to provide a uniform guide for those inertial angular sensors that have not been covered elsewhere. Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Status Inactive-Reserved Standard Corrigendum 671-1985\/Cor 1-2010 Board Approval 1983-06-23 History ANSI Approved: 1992-05-06 Published: 1984-11-30 Reaffirmed: 2008-12-10 Inactivated Date: 2019-11-07 Working Group Details Society IEEE Aerospace and Electronic Systems Society Learn More Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Working Group SENSR_WG - Sensors Working Group Learn More IEEE Program Manager Soo Kim Contact Working Group Chair Harry Davis Active Projects Active Standards Superseded Standards Inactive-Withdrawn Standards Inactive-Reserved Standards P1431 Standard for Specifying and Testing Coriolis Vibratory Gyros This standard defines requirements and test procedures for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1293-2018 IEEE Standard Specification Format Guide and Test Procedure for Linear Single-Axis, Nongyroscopic Accelerometers The specification and test requirements for a linear, single-axis, nongyroscopic accelerometer for use in inertial navigation, guidance, and leveling systems are defined. A standard specification guide and a compilation of recommended test procedures for such accelerometers are provided. Informative annexes are given on the various types of such accelerometers (force or pendulous torque rebalance with analog or digital output, vibrating beam, and micromechanical) and error effects, on filtering, noise, and transient analysis techniques, and on calibration and modeling techniques (multipoint tumble analysis, vibration and shock test analyses, and geophysical effects in inertial instrument testing). Learn More 528-2019 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-2020 IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently used in the industry. Learn More 1293-1998\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Linear,Single-Axis, Nongyroscopic Accelerometers Corrigendum 1: Changes to Annex K and Annex L Corrigendum to IEEE Std 1293-1998. Specification and test requirements for linear, single-axis, nongyroscopic accelerometers for use as a sensor in attitude control systems, linear displacement measuring systems, and linear rate measuring systems are defined. The specification format guide and test procedure standard applies to force-rebalance accelerometers (pendulous or translational proof mass), vibrating beam accelerometers (VBAs), and micromechanical accelerometers that range from lesser accuracy to high accuracy devices. Learn More 528-2001 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-1997 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros Specification and test requirements for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis IFOG is provided. A compilation of recommended procedures for testing a fiber optic gyro, derived from those presently used in the industry, is also provided. Learn More 952-1997\/Cor 1-2016 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros -- Corrigendum 1: Figure 1 and Subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1 Errors identified in IEEE Std 952-1997 are corrected in this corrigendum. Corrections are made to Figure 1 and in subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1. Learn More No Inactive-Withdrawn Standards 1431-2004 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros Specification and test requirements for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A stadard specification format guide for the preparation of a single-axis CVG is provided. A complilation of recommended procedures for testing a CVG, derived from those presently used in the industry, is also provided. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1431-2004\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros - Corrigendum 1 Corrigendum to IEEE Std 1431-2004. Learn More 1554-2005 IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice. Learn More 292-1969 IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch closure(s) at angular rates (exceeding,less than)______ (+,-,u00b1)______ degrees per second]. Learn More 293-1969 IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide in the preparation of Section 4 of a specification that follows the format of IEEE Std 292, Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros. Learn More 293-1969\/Cor 1-2014 IEEE Standard for IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros -- Corrigendum 1: Table 1 Heading Correction to Table 1 on page 14 of IEEE Std 293-1969 Learn More 517-1974 IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given. Learn More 529-1980 Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyroscope specification is presented. Recommended procedures for testing a rate-integrating gyroscope are compiled. This standard, when combined with IEEE Std 517-1974 (R1980), defines the requirements and test procedures in terms of characteristics unique to the gyroscope or those applications in which the dynamic angular inputs are significantly greater than the limitations identified in IEEE Std 517. Learn More 529-1980\/Cor 1-2017 IEEE Standard Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros - Corrigendum 1: 3.3.9.2.2, 3.6.4.1.1, 3.6.4.1.2, 6.3, and 10.10.4.1 Corrections are made by this corrigendum to material already published in IEEE Std 529-1980. Learn More 647-2006 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Laser Gyros Specification and test requirements for a single-axis ring laser gyro (RLG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis RLG is provided. A compilation of recommended procedures for testing an RLG, derived from those presently used in the industry, is also provided. Learn More 671-1985\/Cor 1-2010 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement Corrigendum 1: 4.7.2.6 Short-Term Stability and Annex A Sensor Dynamic Block Diagrams IEEE Std 671-1985 provides specifications and test requirements for a non-gyroscopic inertial angular sensor that may measure angular jerk, acceleration, rate, or displacement with or without response down to zero frequency. A standard specification format is provided. A compilation of recommended test procedures, derived from those presently used in the industry, is also provided. Informative annexes cover design features and theoretical principles of operation. This corrigendum makes changes to 4.7.2.6 to delete a sentence that does not belong there, to add a subclause that was inadvertently left out, and to renumber the existing subclauses. Changes are also being made to fix the block diagrams in Annex A, to correct a misspelling of inertia, and to add a missing symbol. Learn More 813-1988 IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also given. The requirements and test procedures are defined in terms unique to the DTG. They cover applications of the gyro as an angular motion sensor in navigation and control systems. They apply to two modes of use: (1) as a strap-down sensor in operating environments typical of aircraft and missile applications, and (2) as a sensor in gimballed platform applications in which the dynamic angular inputs to which the gyro is subjected are benign relative to the accuracy required. In the case of the strap-down DTG, the characteristics of the external capture loops are considered to the extent necessary to define the gyro performance. Learn More 836-2009 IEEE Recommended Practice for Precision Centrifuge Testing of Linear Accelerometers This recommended practice describes the conduct and analysis of precision tests that are to be performed on linear accelerometers using centrifuge techniques. The term u201cprecision,u201d in this context, refers to tests that are conducted to evaluate accelerometer parameters, as opposed to those conducted to establish environmental survivability only. Evaluation may take the form of determining the coefficients of the accelerometer''s model equation, except for bias and scale factor, which are most accurately determined by static multi-position tests. Alternatively, evaluation may only establish that the accelerometer output complies with specific error limit criteria. 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A not-for-profit organization, IEEE is the world\u2019s largest technical professional organization dedicated to advancing technology for the benefit of humanity. Subscribe Newswire Sign up for our monthly newsletter to learn about new developments, including resources, insights and more. ","doc_title_t":"IEEE SA - IEEE 671-1985","doc_type_l":"text\/html","meta_description_l":"A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been developed to meet needs not easily met by traditional spinning-rotor gyroscopes. A test procedure for verifying that the specifications have been met is given. The standard is not intended to compete with existing standards for specific devices with highly specific models and error sources, such as spring-restrained rate gyros, but to provide a uniform guide for those inertial angular sensors that have not been covered elsewhere.","meta_designation_l":"IEEE 671-1985","meta_keywords_la":["Aerospace Electronics"],"meta_title_t":"IEEE SA - IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement","meta_topic_la":["Aerospace Electronics"],"meta_type_la":["Standard"]}},{"id":"ee508f6840ba448a4304c2e4a0881d6b43ff6e507e255fdc9ec1771cb43ef2546f54f43ab58a42a5b8b4993d3c055a06a9ee307f6c930debe918f8c3048366c7","fields":{"meta_keywords_la":["Power and Energy"],"doc_type_l":"text\/html","meta_type_la":["Page"],"meta_description_l":"View the detailed list of new and revised standards projects that were approved by the IEEE-SA Standards Board, as well as administrative withdrawals","doc_id_l":"https:\/\/standards.ieee.org\/about\/sasb\/sba\/june2019\/","doc_title_t":"IEEE SA - June 2019","doc_text_t":"IEEE SA - June 2019 IEEE.org IEEE Xplore Digital Library IEEE Standards IEEE Spectrum More Sites eTools Standards Access Standards Search Standards Standards Development Standards Adoption Choose from the many ways to access IEEE SA Standards. 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Use of this website signifies your agreement to the IEEE Terms and Conditions . A not-for-profit organization, IEEE is the world\u2019s largest technical professional organization dedicated to advancing technology for the benefit of humanity. Subscribe Newswire Sign up for our monthly newsletter to learn about new developments, including resources, insights and more. "}},{"id":"a987f234b815c04d51196a5861dce1ab4f2a67a7df6f37238f67bb5387af80050e142c401c7c38a091478a9f9de39f5bb24d00c179180953adc632f16a51cd68","fields":{"doc_id_l":"https:\/\/standards.ieee.org\/ieee\/813\/1200\/","doc_text_t":"IEEE SA - IEEE 813-1988 IEEE.org IEEE Xplore Digital Library IEEE Standards IEEE Spectrum More Sites eTools Standards Access Standards Search Standards Standards Development Standards Adoption Products & Programs Alliance Management Services Conformity Assessment & Certification IEEE SA Open Source Industry Affiliate Network (IAN) Industry Connections The National Electrical Safety Code\u00ae (NESC\u00ae) Registration Authority Government Engagement Program on Standards (GEPS) Standards Fellowship All Products & Programs Focuses Artificial Intelligence Systems (AIS) Connectivity & Telecom Energy Foundational Technologies Healthcare and Life Sciences Mobility Government Engagement Get Involved Events IEEE SA Membership How to Get Involved Resources Training & Development News IEEE SA Newsletter Standards Store MAC ADDRESS Inactive-Reserved Standard IEEE 813-1988 IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros Purchase Access via Subscription Home Standards IEEE 813-1988 A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also given. The requirements and test procedures are defined in terms unique to the DTG. They cover applications of the gyro as an angular motion sensor in navigation and control systems. They apply to two modes of use: (1) as a strap-down sensor in operating environments typical of aircraft and missile applications, and (2) as a sensor in gimballed platform applications in which the dynamic angular inputs to which the gyro is subjected are benign relative to the accuracy required. In the case of the strap-down DTG, the characteristics of the external capture loops are considered to the extent necessary to define the gyro performance. Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Status Inactive-Reserved Standard PAR Approval 1979-12-28 Board Approval 1988-08-17 History ANSI Approved: 1989-05-04 ANSI Withdrawn Date: 2016-08-19 Published: 1989-06-05 Reaffirmed: 2011-12-07 Inactivated Date: 2022-03-24 Working Group Details Society IEEE Aerospace and Electronic Systems Society Learn More Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Working Group SENSR_WG - Sensors Working Group Learn More IEEE Program Manager Soo Kim Contact Working Group Chair Harry Davis Active Projects Active Standards Superseded Standards Inactive-Withdrawn Standards Inactive-Reserved Standards P1431 Standard for Specifying and Testing Coriolis Vibratory Gyros This standard defines requirements and test procedures for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1293-2018 IEEE Standard Specification Format Guide and Test Procedure for Linear Single-Axis, Nongyroscopic Accelerometers The specification and test requirements for a linear, single-axis, nongyroscopic accelerometer for use in inertial navigation, guidance, and leveling systems are defined. A standard specification guide and a compilation of recommended test procedures for such accelerometers are provided. Informative annexes are given on the various types of such accelerometers (force or pendulous torque rebalance with analog or digital output, vibrating beam, and micromechanical) and error effects, on filtering, noise, and transient analysis techniques, and on calibration and modeling techniques (multipoint tumble analysis, vibration and shock test analyses, and geophysical effects in inertial instrument testing). Learn More 528-2019 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-2020 IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently used in the industry. Learn More 1293-1998\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Linear,Single-Axis, Nongyroscopic Accelerometers Corrigendum 1: Changes to Annex K and Annex L Corrigendum to IEEE Std 1293-1998. Specification and test requirements for linear, single-axis, nongyroscopic accelerometers for use as a sensor in attitude control systems, linear displacement measuring systems, and linear rate measuring systems are defined. The specification format guide and test procedure standard applies to force-rebalance accelerometers (pendulous or translational proof mass), vibrating beam accelerometers (VBAs), and micromechanical accelerometers that range from lesser accuracy to high accuracy devices. Learn More 528-2001 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-1997 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros Specification and test requirements for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis IFOG is provided. A compilation of recommended procedures for testing a fiber optic gyro, derived from those presently used in the industry, is also provided. Learn More 952-1997\/Cor 1-2016 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros -- Corrigendum 1: Figure 1 and Subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1 Errors identified in IEEE Std 952-1997 are corrected in this corrigendum. Corrections are made to Figure 1 and in subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1. Learn More No Inactive-Withdrawn Standards 1431-2004 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros Specification and test requirements for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A stadard specification format guide for the preparation of a single-axis CVG is provided. A complilation of recommended procedures for testing a CVG, derived from those presently used in the industry, is also provided. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1431-2004\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros - Corrigendum 1 Corrigendum to IEEE Std 1431-2004. Learn More 1554-2005 IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice. Learn More 292-1969 IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch closure(s) at angular rates (exceeding,less than)______ (+,-,u00b1)______ degrees per second]. Learn More 293-1969 IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide in the preparation of Section 4 of a specification that follows the format of IEEE Std 292, Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros. Learn More 293-1969\/Cor 1-2014 IEEE Standard for IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros -- Corrigendum 1: Table 1 Heading Correction to Table 1 on page 14 of IEEE Std 293-1969 Learn More 517-1974 IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given. Learn More 529-1980 Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyroscope specification is presented. Recommended procedures for testing a rate-integrating gyroscope are compiled. This standard, when combined with IEEE Std 517-1974 (R1980), defines the requirements and test procedures in terms of characteristics unique to the gyroscope or those applications in which the dynamic angular inputs are significantly greater than the limitations identified in IEEE Std 517. Learn More 529-1980\/Cor 1-2017 IEEE Standard Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros - Corrigendum 1: 3.3.9.2.2, 3.6.4.1.1, 3.6.4.1.2, 6.3, and 10.10.4.1 Corrections are made by this corrigendum to material already published in IEEE Std 529-1980. Learn More 647-2006 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Laser Gyros Specification and test requirements for a single-axis ring laser gyro (RLG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis RLG is provided. A compilation of recommended procedures for testing an RLG, derived from those presently used in the industry, is also provided. Learn More 671-1985 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been developed to meet needs not easily met by traditional spinning-rotor gyroscopes. A test procedure for verifying that the specifications have been met is given. The standard is not intended to compete with existing standards for specific devices with highly specific models and error sources, such as spring-restrained rate gyros, but to provide a uniform guide for those inertial angular sensors that have not been covered elsewhere. Learn More 671-1985\/Cor 1-2010 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement Corrigendum 1: 4.7.2.6 Short-Term Stability and Annex A Sensor Dynamic Block Diagrams IEEE Std 671-1985 provides specifications and test requirements for a non-gyroscopic inertial angular sensor that may measure angular jerk, acceleration, rate, or displacement with or without response down to zero frequency. A standard specification format is provided. A compilation of recommended test procedures, derived from those presently used in the industry, is also provided. Informative annexes cover design features and theoretical principles of operation. This corrigendum makes changes to 4.7.2.6 to delete a sentence that does not belong there, to add a subclause that was inadvertently left out, and to renumber the existing subclauses. Changes are also being made to fix the block diagrams in Annex A, to correct a misspelling of inertia, and to add a missing symbol. Learn More 836-2009 IEEE Recommended Practice for Precision Centrifuge Testing of Linear Accelerometers This recommended practice describes the conduct and analysis of precision tests that are to be performed on linear accelerometers using centrifuge techniques. The term u201cprecision,u201d in this context, refers to tests that are conducted to evaluate accelerometer parameters, as opposed to those conducted to establish environmental survivability only. Evaluation may take the form of determining the coefficients of the accelerometer''s model equation, except for bias and scale factor, which are most accurately determined by static multi-position tests. Alternatively, evaluation may only establish that the accelerometer output complies with specific error limit criteria. 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A not-for-profit organization, IEEE is the world\u2019s largest technical professional organization dedicated to advancing technology for the benefit of humanity. Subscribe Newswire Sign up for our monthly newsletter to learn about new developments, including resources, insights and more. ","doc_title_t":"IEEE SA - IEEE 813-1988","doc_type_l":"text\/html","meta_description_l":"A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also given. The requirements and test procedures are defined in terms unique to the DTG. They cover applications of the gyro as an angular motion sensor in navigation and control systems. They apply to two modes of use: (1) as a strap-down sensor in operating environments typical of aircraft and missile applications, and (2) as a sensor in gimballed platform applications in which the dynamic angular inputs to which the gyro is subjected are benign relative to the accuracy required. In the case of the strap-down DTG, the characteristics of the external capture loops are considered to the extent necessary to define the gyro performance.","meta_designation_l":"IEEE 813-1988","meta_keywords_la":["Aerospace Electronics"],"meta_title_t":"IEEE SA - IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros","meta_topic_la":["Aerospace Electronics"],"meta_type_la":["Standard"]}},{"id":"52eae60b2e77539af2d00032c19addb836f63a63838a98a1e1415ce8b7dc2251a177a0b3bc0831e7f951dfebfee24916a61d3623dbfda9f11f2e8eea97d28e2f","fields":{"doc_id_l":"https:\/\/standards.ieee.org\/ieee\/1554\/2292\/","doc_text_t":"IEEE SA - IEEE 1554-2005 IEEE.org IEEE Xplore Digital Library IEEE Standards IEEE Spectrum More Sites eTools Standards Access Standards Search Standards Standards Development Standards Adoption Products & Programs Alliance Management Services Conformity Assessment & Certification IEEE SA Open Source Industry Affiliate Network (IAN) Industry Connections The National Electrical Safety Code\u00ae (NESC\u00ae) Registration Authority Government Engagement Program on Standards (GEPS) Standards Fellowship All Products & Programs Focuses Artificial Intelligence Systems (AIS) Connectivity & Telecom Energy Foundational Technologies Healthcare and Life Sciences Mobility Government Engagement Get Involved Events IEEE SA Membership How to Get Involved Resources Training & Development News IEEE SA Newsletter Standards Store MAC ADDRESS Inactive-Reserved Standard IEEE 1554-2005 IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis Purchase Access via Subscription Home Standards IEEE 1554-2005 Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice. Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Status Inactive-Reserved Standard PAR Approval 1999-09-16 Board Approval 2005-06-09 History ANSI Approved: 2005-10-05 Published: 2005-11-28 Reaffirmed: 2011-03-31 Inactivated Date: 2022-03-24 Additional Resources Erratas 1554-2005_errata.pdf Working Group Details Society IEEE Aerospace and Electronic Systems Society Learn More Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Working Group SENSR_WG - Sensors Working Group Learn More IEEE Program Manager Soo Kim Contact Working Group Chair Harry Davis Active Projects Active Standards Superseded Standards Inactive-Withdrawn Standards Inactive-Reserved Standards P1431 Standard for Specifying and Testing Coriolis Vibratory Gyros This standard defines requirements and test procedures for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1293-2018 IEEE Standard Specification Format Guide and Test Procedure for Linear Single-Axis, Nongyroscopic Accelerometers The specification and test requirements for a linear, single-axis, nongyroscopic accelerometer for use in inertial navigation, guidance, and leveling systems are defined. A standard specification guide and a compilation of recommended test procedures for such accelerometers are provided. Informative annexes are given on the various types of such accelerometers (force or pendulous torque rebalance with analog or digital output, vibrating beam, and micromechanical) and error effects, on filtering, noise, and transient analysis techniques, and on calibration and modeling techniques (multipoint tumble analysis, vibration and shock test analyses, and geophysical effects in inertial instrument testing). Learn More 528-2019 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-2020 IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently used in the industry. Learn More 1293-1998\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Linear,Single-Axis, Nongyroscopic Accelerometers Corrigendum 1: Changes to Annex K and Annex L Corrigendum to IEEE Std 1293-1998. Specification and test requirements for linear, single-axis, nongyroscopic accelerometers for use as a sensor in attitude control systems, linear displacement measuring systems, and linear rate measuring systems are defined. The specification format guide and test procedure standard applies to force-rebalance accelerometers (pendulous or translational proof mass), vibrating beam accelerometers (VBAs), and micromechanical accelerometers that range from lesser accuracy to high accuracy devices. Learn More 528-2001 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-1997 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros Specification and test requirements for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis IFOG is provided. A compilation of recommended procedures for testing a fiber optic gyro, derived from those presently used in the industry, is also provided. Learn More 952-1997\/Cor 1-2016 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros -- Corrigendum 1: Figure 1 and Subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1 Errors identified in IEEE Std 952-1997 are corrected in this corrigendum. Corrections are made to Figure 1 and in subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1. Learn More No Inactive-Withdrawn Standards 1431-2004 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros Specification and test requirements for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A stadard specification format guide for the preparation of a single-axis CVG is provided. A complilation of recommended procedures for testing a CVG, derived from those presently used in the industry, is also provided. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1431-2004\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros - Corrigendum 1 Corrigendum to IEEE Std 1431-2004. Learn More 292-1969 IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch closure(s) at angular rates (exceeding,less than)______ (+,-,u00b1)______ degrees per second]. Learn More 293-1969 IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide in the preparation of Section 4 of a specification that follows the format of IEEE Std 292, Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros. Learn More 293-1969\/Cor 1-2014 IEEE Standard for IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros -- Corrigendum 1: Table 1 Heading Correction to Table 1 on page 14 of IEEE Std 293-1969 Learn More 517-1974 IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given. Learn More 529-1980 Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyroscope specification is presented. Recommended procedures for testing a rate-integrating gyroscope are compiled. This standard, when combined with IEEE Std 517-1974 (R1980), defines the requirements and test procedures in terms of characteristics unique to the gyroscope or those applications in which the dynamic angular inputs are significantly greater than the limitations identified in IEEE Std 517. Learn More 529-1980\/Cor 1-2017 IEEE Standard Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros - Corrigendum 1: 3.3.9.2.2, 3.6.4.1.1, 3.6.4.1.2, 6.3, and 10.10.4.1 Corrections are made by this corrigendum to material already published in IEEE Std 529-1980. Learn More 647-2006 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Laser Gyros Specification and test requirements for a single-axis ring laser gyro (RLG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis RLG is provided. A compilation of recommended procedures for testing an RLG, derived from those presently used in the industry, is also provided. Learn More 671-1985 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been developed to meet needs not easily met by traditional spinning-rotor gyroscopes. A test procedure for verifying that the specifications have been met is given. The standard is not intended to compete with existing standards for specific devices with highly specific models and error sources, such as spring-restrained rate gyros, but to provide a uniform guide for those inertial angular sensors that have not been covered elsewhere. Learn More 671-1985\/Cor 1-2010 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement Corrigendum 1: 4.7.2.6 Short-Term Stability and Annex A Sensor Dynamic Block Diagrams IEEE Std 671-1985 provides specifications and test requirements for a non-gyroscopic inertial angular sensor that may measure angular jerk, acceleration, rate, or displacement with or without response down to zero frequency. A standard specification format is provided. A compilation of recommended test procedures, derived from those presently used in the industry, is also provided. Informative annexes cover design features and theoretical principles of operation. This corrigendum makes changes to 4.7.2.6 to delete a sentence that does not belong there, to add a subclause that was inadvertently left out, and to renumber the existing subclauses. Changes are also being made to fix the block diagrams in Annex A, to correct a misspelling of inertia, and to add a missing symbol. Learn More 813-1988 IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also given. The requirements and test procedures are defined in terms unique to the DTG. They cover applications of the gyro as an angular motion sensor in navigation and control systems. They apply to two modes of use: (1) as a strap-down sensor in operating environments typical of aircraft and missile applications, and (2) as a sensor in gimballed platform applications in which the dynamic angular inputs to which the gyro is subjected are benign relative to the accuracy required. In the case of the strap-down DTG, the characteristics of the external capture loops are considered to the extent necessary to define the gyro performance. Learn More 836-2009 IEEE Recommended Practice for Precision Centrifuge Testing of Linear Accelerometers This recommended practice describes the conduct and analysis of precision tests that are to be performed on linear accelerometers using centrifuge techniques. The term u201cprecision,u201d in this context, refers to tests that are conducted to evaluate accelerometer parameters, as opposed to those conducted to establish environmental survivability only. Evaluation may take the form of determining the coefficients of the accelerometer''s model equation, except for bias and scale factor, which are most accurately determined by static multi-position tests. Alternatively, evaluation may only establish that the accelerometer output complies with specific error limit criteria. 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A not-for-profit organization, IEEE is the world\u2019s largest technical professional organization dedicated to advancing technology for the benefit of humanity. Subscribe Newswire Sign up for our monthly newsletter to learn about new developments, including resources, insights and more. ","doc_title_t":"IEEE SA - IEEE 1554-2005","doc_type_l":"text\/html","meta_description_l":"Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice.","meta_designation_l":"IEEE 1554-2005","meta_keywords_la":["Aerospace Electronics"],"meta_title_t":"IEEE SA - IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis","meta_topic_la":["Aerospace Electronics"],"meta_type_la":["Standard"]}},{"id":"0e5f59ed4630b7396c4a857f43f6bb32af4c28844fefb77ff93fe62204b6b900a7db16a6b235b40889e7c1b34cbfd885f9f106827f93026cac353fc730a1df39","fields":{"doc_id_l":"https:\/\/standards.ieee.org\/ieee\/292\/485\/","doc_text_t":"IEEE SA - IEEE 292-1969 IEEE.org IEEE Xplore Digital Library IEEE Standards IEEE Spectrum More Sites eTools Standards Access Standards Search Standards Standards Development Standards Adoption Products & Programs Alliance Management Services Conformity Assessment & Certification IEEE SA Open Source Industry Affiliate Network (IAN) Industry Connections The National Electrical Safety Code\u00ae (NESC\u00ae) Registration Authority Government Engagement Program on Standards (GEPS) Standards Fellowship All Products & Programs Focuses Artificial Intelligence Systems (AIS) Connectivity & Telecom Energy Foundational Technologies Healthcare and Life Sciences Mobility Government Engagement Get Involved Events IEEE SA Membership How to Get Involved Resources Training & Development News IEEE SA Newsletter Standards Store MAC ADDRESS Inactive-Reserved Standard IEEE 292-1969 IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros Purchase Access via Subscription Home Standards IEEE 292-1969 This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch closure(s) at angular rates (exceeding,less than)______ (+,-,\u00b1)______ degrees per second]. Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Status Inactive-Reserved Standard History ANSI Approved: 1986-11-17 Published: 1968-11-30 Reaffirmed: 2010-06-17 Inactivated Date: 2021-03-25 Additional Resources Erratas 292-1969_errata.pdf Working Group Details Society IEEE Aerospace and Electronic Systems Society Learn More Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Working Group SENSR_WG - Sensors Working Group Learn More IEEE Program Manager Soo Kim Contact Working Group Chair Harry Davis Active Projects Active Standards Superseded Standards Inactive-Withdrawn Standards Inactive-Reserved Standards P1431 Standard for Specifying and Testing Coriolis Vibratory Gyros This standard defines requirements and test procedures for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1293-2018 IEEE Standard Specification Format Guide and Test Procedure for Linear Single-Axis, Nongyroscopic Accelerometers The specification and test requirements for a linear, single-axis, nongyroscopic accelerometer for use in inertial navigation, guidance, and leveling systems are defined. A standard specification guide and a compilation of recommended test procedures for such accelerometers are provided. Informative annexes are given on the various types of such accelerometers (force or pendulous torque rebalance with analog or digital output, vibrating beam, and micromechanical) and error effects, on filtering, noise, and transient analysis techniques, and on calibration and modeling techniques (multipoint tumble analysis, vibration and shock test analyses, and geophysical effects in inertial instrument testing). Learn More 528-2019 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-2020 IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently used in the industry. Learn More 1293-1998\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Linear,Single-Axis, Nongyroscopic Accelerometers Corrigendum 1: Changes to Annex K and Annex L Corrigendum to IEEE Std 1293-1998. Specification and test requirements for linear, single-axis, nongyroscopic accelerometers for use as a sensor in attitude control systems, linear displacement measuring systems, and linear rate measuring systems are defined. The specification format guide and test procedure standard applies to force-rebalance accelerometers (pendulous or translational proof mass), vibrating beam accelerometers (VBAs), and micromechanical accelerometers that range from lesser accuracy to high accuracy devices. Learn More 528-2001 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-1997 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros Specification and test requirements for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis IFOG is provided. A compilation of recommended procedures for testing a fiber optic gyro, derived from those presently used in the industry, is also provided. Learn More 952-1997\/Cor 1-2016 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros -- Corrigendum 1: Figure 1 and Subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1 Errors identified in IEEE Std 952-1997 are corrected in this corrigendum. Corrections are made to Figure 1 and in subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1. Learn More No Inactive-Withdrawn Standards 1431-2004 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros Specification and test requirements for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A stadard specification format guide for the preparation of a single-axis CVG is provided. A complilation of recommended procedures for testing a CVG, derived from those presently used in the industry, is also provided. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1431-2004\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros - Corrigendum 1 Corrigendum to IEEE Std 1431-2004. Learn More 1554-2005 IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice. Learn More 293-1969 IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide in the preparation of Section 4 of a specification that follows the format of IEEE Std 292, Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros. Learn More 293-1969\/Cor 1-2014 IEEE Standard for IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros -- Corrigendum 1: Table 1 Heading Correction to Table 1 on page 14 of IEEE Std 293-1969 Learn More 517-1974 IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given. Learn More 529-1980 Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyroscope specification is presented. Recommended procedures for testing a rate-integrating gyroscope are compiled. This standard, when combined with IEEE Std 517-1974 (R1980), defines the requirements and test procedures in terms of characteristics unique to the gyroscope or those applications in which the dynamic angular inputs are significantly greater than the limitations identified in IEEE Std 517. Learn More 529-1980\/Cor 1-2017 IEEE Standard Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros - Corrigendum 1: 3.3.9.2.2, 3.6.4.1.1, 3.6.4.1.2, 6.3, and 10.10.4.1 Corrections are made by this corrigendum to material already published in IEEE Std 529-1980. Learn More 647-2006 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Laser Gyros Specification and test requirements for a single-axis ring laser gyro (RLG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis RLG is provided. A compilation of recommended procedures for testing an RLG, derived from those presently used in the industry, is also provided. Learn More 671-1985 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been developed to meet needs not easily met by traditional spinning-rotor gyroscopes. A test procedure for verifying that the specifications have been met is given. The standard is not intended to compete with existing standards for specific devices with highly specific models and error sources, such as spring-restrained rate gyros, but to provide a uniform guide for those inertial angular sensors that have not been covered elsewhere. Learn More 671-1985\/Cor 1-2010 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement Corrigendum 1: 4.7.2.6 Short-Term Stability and Annex A Sensor Dynamic Block Diagrams IEEE Std 671-1985 provides specifications and test requirements for a non-gyroscopic inertial angular sensor that may measure angular jerk, acceleration, rate, or displacement with or without response down to zero frequency. A standard specification format is provided. A compilation of recommended test procedures, derived from those presently used in the industry, is also provided. Informative annexes cover design features and theoretical principles of operation. This corrigendum makes changes to 4.7.2.6 to delete a sentence that does not belong there, to add a subclause that was inadvertently left out, and to renumber the existing subclauses. Changes are also being made to fix the block diagrams in Annex A, to correct a misspelling of inertia, and to add a missing symbol. Learn More 813-1988 IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also given. The requirements and test procedures are defined in terms unique to the DTG. They cover applications of the gyro as an angular motion sensor in navigation and control systems. They apply to two modes of use: (1) as a strap-down sensor in operating environments typical of aircraft and missile applications, and (2) as a sensor in gimballed platform applications in which the dynamic angular inputs to which the gyro is subjected are benign relative to the accuracy required. In the case of the strap-down DTG, the characteristics of the external capture loops are considered to the extent necessary to define the gyro performance. Learn More 836-2009 IEEE Recommended Practice for Precision Centrifuge Testing of Linear Accelerometers This recommended practice describes the conduct and analysis of precision tests that are to be performed on linear accelerometers using centrifuge techniques. The term u201cprecision,u201d in this context, refers to tests that are conducted to evaluate accelerometer parameters, as opposed to those conducted to establish environmental survivability only. Evaluation may take the form of determining the coefficients of the accelerometer''s model equation, except for bias and scale factor, which are most accurately determined by static multi-position tests. Alternatively, evaluation may only establish that the accelerometer output complies with specific error limit criteria. Learn More Facebook Twitter LinkedIn Instagram YouTube IEEE SA About Us IEEE SA Membership Entity Program Distributor Program Training & Development Policies & Procedures Contact Us Board of Governors About Board of Governors Awards Committee Corporate Advisory Group Industry Connections Committee Registration Authority Committee Strategic Planning Coordination Committee Standards Board About Standards Board Board Approvals Audit Committee New Standards Committee Patent Committee Procedures Committee Standards Review Committee News & Events News IEEE SA Newsletter Events Home Sitemap Contact & Support Accessibility Nondiscrimination Policy IEEE Ethics Reporting IEEE Privacy Policy IEEE SA Copyright Policy \u00a9 Copyright 2021 IEEE \u2013 All rights reserved. Use of this website signifies your agreement to the IEEE Terms and Conditions . A not-for-profit organization, IEEE is the world\u2019s largest technical professional organization dedicated to advancing technology for the benefit of humanity. Subscribe Newswire Sign up for our monthly newsletter to learn about new developments, including resources, insights and more. ","doc_title_t":"IEEE SA - IEEE 292-1969","doc_type_l":"text\/html","meta_description_l":"This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch closure(s) at angular rates (exceeding,less than)______ (+,-,\u00b1)______ degrees per second].","meta_designation_l":"IEEE 292-1969","meta_keywords_la":["Aerospace Electronics"],"meta_title_t":"IEEE SA - IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros","meta_topic_la":["Aerospace Electronics"],"meta_type_la":["Standard"]}},{"id":"994a2773a3f87366d9e7596ae1a277954c2c4d5f654e59ddbb8d2e5c8d83027a101d36188dbe0e50e60d6d3cb6d58028038c31c169368300a82ade2d172ce459","fields":{"doc_id_l":"https:\/\/standards.ieee.org\/ieee\/293\/486\/","doc_text_t":"IEEE SA - IEEE 293-1969 IEEE.org IEEE Xplore Digital Library IEEE Standards IEEE Spectrum More Sites eTools Standards Access Standards Search Standards Standards Development Standards Adoption Products & Programs Alliance Management Services Conformity Assessment & Certification IEEE SA Open Source Industry Affiliate Network (IAN) Industry Connections The National Electrical Safety Code\u00ae (NESC\u00ae) Registration Authority Government Engagement Program on Standards (GEPS) Standards Fellowship All Products & Programs Focuses Artificial Intelligence Systems (AIS) Connectivity & Telecom Energy Foundational Technologies Healthcare and Life Sciences Mobility Government Engagement Get Involved Events IEEE SA Membership How to Get Involved Resources Training & Development News IEEE SA Newsletter Standards Store MAC ADDRESS Inactive-Reserved Standard IEEE 293-1969 IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros Purchase Access via Subscription Home Standards IEEE 293-1969 Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide in the preparation of Section 4 of a specification that follows the format of IEEE Std 292, Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros. Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Status Inactive-Reserved Standard Corrigendum 293-1969\/Cor 1-2014 History ANSI Approved: 1986-11-17 Published: 1968-11-30 Reaffirmed: 2010-06-17 Inactivated Date: 2021-03-25 Working Group Details Society IEEE Aerospace and Electronic Systems Society Learn More Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Working Group SENSR_WG - Sensors Working Group Learn More IEEE Program Manager Soo Kim Contact Working Group Chair Harry Davis Active Projects Active Standards Superseded Standards Inactive-Withdrawn Standards Inactive-Reserved Standards P1431 Standard for Specifying and Testing Coriolis Vibratory Gyros This standard defines requirements and test procedures for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1293-2018 IEEE Standard Specification Format Guide and Test Procedure for Linear Single-Axis, Nongyroscopic Accelerometers The specification and test requirements for a linear, single-axis, nongyroscopic accelerometer for use in inertial navigation, guidance, and leveling systems are defined. A standard specification guide and a compilation of recommended test procedures for such accelerometers are provided. Informative annexes are given on the various types of such accelerometers (force or pendulous torque rebalance with analog or digital output, vibrating beam, and micromechanical) and error effects, on filtering, noise, and transient analysis techniques, and on calibration and modeling techniques (multipoint tumble analysis, vibration and shock test analyses, and geophysical effects in inertial instrument testing). Learn More 528-2019 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-2020 IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently used in the industry. Learn More 1293-1998\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Linear,Single-Axis, Nongyroscopic Accelerometers Corrigendum 1: Changes to Annex K and Annex L Corrigendum to IEEE Std 1293-1998. Specification and test requirements for linear, single-axis, nongyroscopic accelerometers for use as a sensor in attitude control systems, linear displacement measuring systems, and linear rate measuring systems are defined. The specification format guide and test procedure standard applies to force-rebalance accelerometers (pendulous or translational proof mass), vibrating beam accelerometers (VBAs), and micromechanical accelerometers that range from lesser accuracy to high accuracy devices. Learn More 528-2001 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-1997 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros Specification and test requirements for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis IFOG is provided. A compilation of recommended procedures for testing a fiber optic gyro, derived from those presently used in the industry, is also provided. Learn More 952-1997\/Cor 1-2016 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros -- Corrigendum 1: Figure 1 and Subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1 Errors identified in IEEE Std 952-1997 are corrected in this corrigendum. Corrections are made to Figure 1 and in subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1. Learn More No Inactive-Withdrawn Standards 1431-2004 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros Specification and test requirements for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A stadard specification format guide for the preparation of a single-axis CVG is provided. A complilation of recommended procedures for testing a CVG, derived from those presently used in the industry, is also provided. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1431-2004\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros - Corrigendum 1 Corrigendum to IEEE Std 1431-2004. Learn More 1554-2005 IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice. Learn More 292-1969 IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch closure(s) at angular rates (exceeding,less than)______ (+,-,u00b1)______ degrees per second]. Learn More 293-1969\/Cor 1-2014 IEEE Standard for IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros -- Corrigendum 1: Table 1 Heading Correction to Table 1 on page 14 of IEEE Std 293-1969 Learn More 517-1974 IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given. Learn More 529-1980 Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyroscope specification is presented. Recommended procedures for testing a rate-integrating gyroscope are compiled. This standard, when combined with IEEE Std 517-1974 (R1980), defines the requirements and test procedures in terms of characteristics unique to the gyroscope or those applications in which the dynamic angular inputs are significantly greater than the limitations identified in IEEE Std 517. Learn More 529-1980\/Cor 1-2017 IEEE Standard Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros - Corrigendum 1: 3.3.9.2.2, 3.6.4.1.1, 3.6.4.1.2, 6.3, and 10.10.4.1 Corrections are made by this corrigendum to material already published in IEEE Std 529-1980. Learn More 647-2006 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Laser Gyros Specification and test requirements for a single-axis ring laser gyro (RLG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis RLG is provided. A compilation of recommended procedures for testing an RLG, derived from those presently used in the industry, is also provided. Learn More 671-1985 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been developed to meet needs not easily met by traditional spinning-rotor gyroscopes. A test procedure for verifying that the specifications have been met is given. The standard is not intended to compete with existing standards for specific devices with highly specific models and error sources, such as spring-restrained rate gyros, but to provide a uniform guide for those inertial angular sensors that have not been covered elsewhere. Learn More 671-1985\/Cor 1-2010 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement Corrigendum 1: 4.7.2.6 Short-Term Stability and Annex A Sensor Dynamic Block Diagrams IEEE Std 671-1985 provides specifications and test requirements for a non-gyroscopic inertial angular sensor that may measure angular jerk, acceleration, rate, or displacement with or without response down to zero frequency. A standard specification format is provided. A compilation of recommended test procedures, derived from those presently used in the industry, is also provided. Informative annexes cover design features and theoretical principles of operation. This corrigendum makes changes to 4.7.2.6 to delete a sentence that does not belong there, to add a subclause that was inadvertently left out, and to renumber the existing subclauses. Changes are also being made to fix the block diagrams in Annex A, to correct a misspelling of inertia, and to add a missing symbol. Learn More 813-1988 IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also given. The requirements and test procedures are defined in terms unique to the DTG. They cover applications of the gyro as an angular motion sensor in navigation and control systems. They apply to two modes of use: (1) as a strap-down sensor in operating environments typical of aircraft and missile applications, and (2) as a sensor in gimballed platform applications in which the dynamic angular inputs to which the gyro is subjected are benign relative to the accuracy required. In the case of the strap-down DTG, the characteristics of the external capture loops are considered to the extent necessary to define the gyro performance. Learn More 836-2009 IEEE Recommended Practice for Precision Centrifuge Testing of Linear Accelerometers This recommended practice describes the conduct and analysis of precision tests that are to be performed on linear accelerometers using centrifuge techniques. The term u201cprecision,u201d in this context, refers to tests that are conducted to evaluate accelerometer parameters, as opposed to those conducted to establish environmental survivability only. Evaluation may take the form of determining the coefficients of the accelerometer''s model equation, except for bias and scale factor, which are most accurately determined by static multi-position tests. Alternatively, evaluation may only establish that the accelerometer output complies with specific error limit criteria. Learn More Facebook Twitter LinkedIn Instagram YouTube IEEE SA About Us IEEE SA Membership Entity Program Distributor Program Training & Development Policies & Procedures Contact Us Board of Governors About Board of Governors Awards Committee Corporate Advisory Group Industry Connections Committee Registration Authority Committee Strategic Planning Coordination Committee Standards Board About Standards Board Board Approvals Audit Committee New Standards Committee Patent Committee Procedures Committee Standards Review Committee News & Events News IEEE SA Newsletter Events Home Sitemap Contact & Support Accessibility Nondiscrimination Policy IEEE Ethics Reporting IEEE Privacy Policy IEEE SA Copyright Policy \u00a9 Copyright 2021 IEEE \u2013 All rights reserved. Use of this website signifies your agreement to the IEEE Terms and Conditions . A not-for-profit organization, IEEE is the world\u2019s largest technical professional organization dedicated to advancing technology for the benefit of humanity. Subscribe Newswire Sign up for our monthly newsletter to learn about new developments, including resources, insights and more. ","doc_title_t":"IEEE SA - IEEE 293-1969","doc_type_l":"text\/html","meta_description_l":"Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide in the preparation of Section 4 of a specification that follows the format of IEEE Std 292, Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros.","meta_designation_l":"IEEE 293-1969","meta_keywords_la":["Aerospace Electronics"],"meta_title_t":"IEEE SA - IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros","meta_topic_la":["Aerospace Electronics"],"meta_type_la":["Standard"]}},{"id":"3fc0c715deec41762b0998457967e6feb2e27945928e2467bfb2f2923a4976a89ba4567595790403dcd8f650e2906a80c9826aa4cd52d5af78f7195707928ce0","fields":{"doc_id_l":"https:\/\/standards.ieee.org\/ieee\/517\/760\/","doc_text_t":"IEEE SA - IEEE 517-1974 IEEE.org IEEE Xplore Digital Library IEEE Standards IEEE Spectrum More Sites eTools Standards Access Standards Search Standards Standards Development Standards Adoption Products & Programs Alliance Management Services Conformity Assessment & Certification IEEE SA Open Source Industry Affiliate Network (IAN) Industry Connections The National Electrical Safety Code\u00ae (NESC\u00ae) Registration Authority Government Engagement Program on Standards (GEPS) Standards Fellowship All Products & Programs Focuses Artificial Intelligence Systems (AIS) Connectivity & Telecom Energy Foundational Technologies Healthcare and Life Sciences Mobility Government Engagement Get Involved Events IEEE SA Membership How to Get Involved Resources Training & Development News IEEE SA Newsletter Standards Store MAC ADDRESS Inactive-Reserved Standard IEEE 517-1974 IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros Purchase Access via Subscription Home Standards IEEE 517-1974 A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given. Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Status Inactive-Reserved Standard Board Approval 1973-12-13 History ANSI Approved: 1983-05-30 Published: 1974-10-17 Reaffirmed: 2010-09-30 Inactivated Date: 2021-03-25 Additional Resources Erratas 517-1974_errata.pdf Working Group Details Society IEEE Aerospace and Electronic Systems Society Learn More Sponsor Committee AES\/GA - Gyro Accelerometer Panel Learn More Working Group SENSR_WG - Sensors Working Group Learn More IEEE Program Manager Soo Kim Contact Working Group Chair Harry Davis Active Projects Active Standards Superseded Standards Inactive-Withdrawn Standards Inactive-Reserved Standards P1431 Standard for Specifying and Testing Coriolis Vibratory Gyros This standard defines requirements and test procedures for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1293-2018 IEEE Standard Specification Format Guide and Test Procedure for Linear Single-Axis, Nongyroscopic Accelerometers The specification and test requirements for a linear, single-axis, nongyroscopic accelerometer for use in inertial navigation, guidance, and leveling systems are defined. A standard specification guide and a compilation of recommended test procedures for such accelerometers are provided. Informative annexes are given on the various types of such accelerometers (force or pendulous torque rebalance with analog or digital output, vibrating beam, and micromechanical) and error effects, on filtering, noise, and transient analysis techniques, and on calibration and modeling techniques (multipoint tumble analysis, vibration and shock test analyses, and geophysical effects in inertial instrument testing). Learn More 528-2019 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-2020 IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently used in the industry. Learn More 1293-1998\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Linear,Single-Axis, Nongyroscopic Accelerometers Corrigendum 1: Changes to Annex K and Annex L Corrigendum to IEEE Std 1293-1998. Specification and test requirements for linear, single-axis, nongyroscopic accelerometers for use as a sensor in attitude control systems, linear displacement measuring systems, and linear rate measuring systems are defined. The specification format guide and test procedure standard applies to force-rebalance accelerometers (pendulous or translational proof mass), vibrating beam accelerometers (VBAs), and micromechanical accelerometers that range from lesser accuracy to high accuracy devices. Learn More 528-2001 IEEE Standard for Inertial Sensor Terminology Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its definition in this standard is usefulness as related to inertial sensor technology. Learn More 952-1997 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros Specification and test requirements for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis IFOG is provided. A compilation of recommended procedures for testing a fiber optic gyro, derived from those presently used in the industry, is also provided. Learn More 952-1997\/Cor 1-2016 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Interferometric Fiber Optic Gyros -- Corrigendum 1: Figure 1 and Subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1 Errors identified in IEEE Std 952-1997 are corrected in this corrigendum. Corrections are made to Figure 1 and in subclauses 5.3.4, 8.3, 12.11.4.3.2, 12.11.4.3.3, 12.11.4.3.4, 12.12.3.1, and 12.12.4.1. Learn More No Inactive-Withdrawn Standards 1431-2004 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros Specification and test requirements for a single-axis Coriolis vibratory gyro (CVG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A stadard specification format guide for the preparation of a single-axis CVG is provided. A complilation of recommended procedures for testing a CVG, derived from those presently used in the industry, is also provided. Informative annexes cover CVG design features and theoretical principles of operation. Learn More 1431-2004\/Cor 1-2008 IEEE Standard Specification Format Guide and Test Procedure for Coriolis Vibratory Gyros - Corrigendum 1 Corrigendum to IEEE Std 1431-2004. Learn More 1554-2005 IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice. Learn More 292-1969 IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch closure(s) at angular rates (exceeding,less than)______ (+,-,u00b1)______ degrees per second]. Learn More 293-1969 IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide in the preparation of Section 4 of a specification that follows the format of IEEE Std 292, Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros. Learn More 293-1969\/Cor 1-2014 IEEE Standard for IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros -- Corrigendum 1: Table 1 Heading Correction to Table 1 on page 14 of IEEE Std 293-1969 Learn More 529-1980 Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros A specification format guide for the preparation of a rate-integrating gyroscope specification is presented. Recommended procedures for testing a rate-integrating gyroscope are compiled. This standard, when combined with IEEE Std 517-1974 (R1980), defines the requirements and test procedures in terms of characteristics unique to the gyroscope or those applications in which the dynamic angular inputs are significantly greater than the limitations identified in IEEE Std 517. Learn More 529-1980\/Cor 1-2017 IEEE Standard Supplement for Strapdown Applications to IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros - Corrigendum 1: 3.3.9.2.2, 3.6.4.1.1, 3.6.4.1.2, 6.3, and 10.10.4.1 Corrections are made by this corrigendum to material already published in IEEE Std 529-1980. Learn More 647-2006 IEEE Standard Specification Format Guide and Test Procedure for Single-Axis Laser Gyros Specification and test requirements for a single-axis ring laser gyro (RLG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. A standard specification format guide for the preparation of a single-axis RLG is provided. A compilation of recommended procedures for testing an RLG, derived from those presently used in the industry, is also provided. Learn More 671-1985 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been developed to meet needs not easily met by traditional spinning-rotor gyroscopes. A test procedure for verifying that the specifications have been met is given. The standard is not intended to compete with existing standards for specific devices with highly specific models and error sources, such as spring-restrained rate gyros, but to provide a uniform guide for those inertial angular sensors that have not been covered elsewhere. Learn More 671-1985\/Cor 1-2010 IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement Corrigendum 1: 4.7.2.6 Short-Term Stability and Annex A Sensor Dynamic Block Diagrams IEEE Std 671-1985 provides specifications and test requirements for a non-gyroscopic inertial angular sensor that may measure angular jerk, acceleration, rate, or displacement with or without response down to zero frequency. A standard specification format is provided. A compilation of recommended test procedures, derived from those presently used in the industry, is also provided. Informative annexes cover design features and theoretical principles of operation. This corrigendum makes changes to 4.7.2.6 to delete a sentence that does not belong there, to add a subclause that was inadvertently left out, and to renumber the existing subclauses. Changes are also being made to fix the block diagrams in Annex A, to correct a misspelling of inertia, and to add a missing symbol. Learn More 813-1988 IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also given. The requirements and test procedures are defined in terms unique to the DTG. They cover applications of the gyro as an angular motion sensor in navigation and control systems. They apply to two modes of use: (1) as a strap-down sensor in operating environments typical of aircraft and missile applications, and (2) as a sensor in gimballed platform applications in which the dynamic angular inputs to which the gyro is subjected are benign relative to the accuracy required. In the case of the strap-down DTG, the characteristics of the external capture loops are considered to the extent necessary to define the gyro performance. Learn More 836-2009 IEEE Recommended Practice for Precision Centrifuge Testing of Linear Accelerometers This recommended practice describes the conduct and analysis of precision tests that are to be performed on linear accelerometers using centrifuge techniques. The term u201cprecision,u201d in this context, refers to tests that are conducted to evaluate accelerometer parameters, as opposed to those conducted to establish environmental survivability only. Evaluation may take the form of determining the coefficients of the accelerometer''s model equation, except for bias and scale factor, which are most accurately determined by static multi-position tests. Alternatively, evaluation may only establish that the accelerometer output complies with specific error limit criteria. Learn More Facebook Twitter LinkedIn Instagram YouTube IEEE SA About Us IEEE SA Membership Entity Program Distributor Program Training & Development Policies & Procedures Contact Us Board of Governors About Board of Governors Awards Committee Corporate Advisory Group Industry Connections Committee Registration Authority Committee Strategic Planning Coordination Committee Standards Board About Standards Board Board Approvals Audit Committee New Standards Committee Patent Committee Procedures Committee Standards Review Committee News & Events News IEEE SA Newsletter Events Home Sitemap Contact & Support Accessibility Nondiscrimination Policy IEEE Ethics Reporting IEEE Privacy Policy IEEE SA Copyright Policy \u00a9 Copyright 2021 IEEE \u2013 All rights reserved. Use of this website signifies your agreement to the IEEE Terms and Conditions . A not-for-profit organization, IEEE is the world\u2019s largest technical professional organization dedicated to advancing technology for the benefit of humanity. Subscribe Newswire Sign up for our monthly newsletter to learn about new developments, including resources, insights and more. ","doc_title_t":"IEEE SA - IEEE 517-1974","doc_type_l":"text\/html","meta_description_l":"A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given.","meta_designation_l":"IEEE 517-1974","meta_keywords_la":["Aerospace Electronics"],"meta_title_t":"IEEE SA - IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros","meta_topic_la":["Aerospace Electronics"],"meta_type_la":["Standard"]}}]},"facets":{"meta_categories_la":{"buckets":[{"value":"NESC","count":2}]},"meta_topic_la":{"buckets":[{"value":"Aerospace Electronics","count":18},{"value":"Aerospace Electronics,Power and Energy","count":3},{"value":"Nuclear Power","count":1}]},"meta_type_la":{"buckets":[{"value":"Standard","count":21},{"value":"Products","count":2},{"value":"Page","count":1},{"value":"Project","count":1}]}}},"html":"

27<\/strong> results found. Results are sorted by relevance.<\/h3>
IEEE 528-2019<\/div>

IEEE Standard for Inertial Sensor Terminology<\/a><\/h4>
Terms and definitions relating to inertial sensors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its…<\/div><\/div>
IEEE 528-2001<\/div>

IEEE Standard for Inertial Sensor Terminology<\/a><\/h4>
Terms and definitions relating to inertial senors are presented in this standard. Usage as understood by the inertial sensor community is given preference over general technical usage of the terms herein. The criterion for inclusion of a term and its…<\/div><\/div>
IEEE 952-2020<\/div>

IEEE Standard for Specifying and Testing Single-Axis Interferometric Fiber Optic Gyros<\/a><\/h4>
Specification and test procedures for a single-axis interferometric fiber optic gyro (IFOG) for use as a sensor in attitude control systems, angular displacement measuring systems, and angular rate measuring systems are defined. The test procedures are derived from those presently…<\/div><\/div>
IEEE 671-1985<\/div>

IEEE Standard Specification Format Guide and Test Procedure for Nongyroscopic Inertial Angular Sensors: Jerk, Acceleration, Velocity, and Displacement<\/a><\/h4>
A guide is presented for the preparation of a specification and test procedure for an inertial angular sensor that provides a common meeting ground of terminology and practice for manufacturers and users of an array of sensors that have been…<\/div><\/div>

June 2019<\/a><\/h4>
View the detailed list of new and revised standards projects that were approved by the IEEE-SA Standards Board, as well as administrative withdrawals<\/div><\/div>
IEEE 813-1988<\/div>

IEEE Specification Format Guide and Test Procedure for Two-Degree-of-Freedom Dynamically Tuned Gyros<\/a><\/h4>
A format guide for the preparation of a two-degree-of-freedom dynamically tuned gyro (DTG) specification is given that provides a common ground of terminology and practice for manufacturers and users. A compilation of recommended procedures for testing a DTG is also…<\/div><\/div>
IEEE 1554-2005<\/div>

IEEE Recommended Practice for Inertial Sensor Test Equipment, Instrumentation, Data Acquisition, and Analysis<\/a><\/h4>
Test equipment, data acquisition equipment, instrumentation, test facilities, and data analysis techniques used in inertial sensor testing are described in this recommended practice.<\/div><\/div>
IEEE 292-1969<\/div>

IEEE Specification Format for Single-Degree-of-Freedom Spring-Restrained Rate Gyros<\/a><\/h4>
This specification defines the requirements for a single-degree-of-freedom spring-restrained rate gyro for [aircraft, missile, spacecraft,______] applications. The rate gyro shall be capable of providing [(dc, ac) voltage outputs proportional to angular rate inputs up to______ degrees per second, a switch…<\/div><\/div>
IEEE 293-1969<\/div>

IEEE Test Procedure for Single-Degree-of-Freedom Spring-Restrained Rate Gyros<\/a><\/h4>
Recommended rate gyro test procedures derived from those currently in use, including test conditions to be considered, are compiled. In some cases alternate methods for measuring a performance characteristic have been included. This standard is intended to be a guide…<\/div><\/div>
IEEE 517-1974<\/div>

IEEE Standard Specification Format Guide and Test Procedure for Single-Degree-of-Freedom Rate-Integrating Gyros<\/a><\/h4>
A specification format guide for the preparation of a rate-integrating gyro specification that provides a common meeting ground of terminology and practice for manufacturers and users is presented. A compilation of recommended procedures for testing a rate-integrating gyro is given.<\/div><\/div>