ASTM E2771-11
(Terminology)Standard Terminology for Homeland Security Applications
Standard Terminology for Homeland Security Applications
SIGNIFICANCE AND USE
In this terminology, definitions used in other ASTM International standards are indicated by following the definition with the designation of the subcommittee responsible for that standard.
SCOPE
1.1 This terminology provides definitions and abbreviations of terms used in ASTM International standards pertaining to homeland security applications.
General Information
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Standards Content (Sample)
NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
Designation:E2771 −11
StandardTerminology for
Homeland Security Applications
This standard is issued under the fixed designation E2771; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 4. Terminology
1.1 This terminology provides definitions and abbreviations 4.1 Definitions:
of terms used in ASTM International standards pertaining to add-on, n—in sensors and detectors for homeland security
homeland security applications. applications, any additional parts that provide tailoring of a
personal detector’s functionality for specific applications.
2. Referenced Documents E2411
2.1 ASTM Standards: 4.2 Abbreviations:
E2411 Specification for Chemical Warfare Vapor Detector GA—nerve agent—common name: tabun, IUPAC name:
(CWVD) O-Ethyl N,N-dimethyl phosphoramidocyanidate
GB—nerve agent—common name: sarin, IUPAC name:
3. Significance and Use
Propan-2-yl methylphosphonofluoridate
3.1 In this terminology, definitions used in other ASTM
GD—nerve agent—common name: soman, IUPAC name:
International standards are indicated by following the defini-
3,3-Dimethylbutan-2-yl methylphosphonofluoridate
tion with the designation of the subcommittee responsible for
GF—nerve agent—common name: cyclosarin, IUPAC name:
that standard.
Cyclohexyl methylphoshonofluoridate
HD—blister agent—common name: distilled mustard, IUPAC
This terminology is under the jurisdiction of ASTM Committee E54 on name: Bis(2-chloroethyl) sulfide
Homeland Security Applications and is the direct responsibility of Subcommittee
L—blister agent—common name: lewisite, IUPAC name:
E54.92 on Terminology.
Current edition approved D
...
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SIGNIFICANCE AND USE
5.1 It is essential for response agency personnel to plan, develop, implement, and train on standardized guidelines that encompass policy, strategy, operations, and tactical decisions prior to responding to a radiological or nuclear incident. Use of this practice is recommended for all levels of the response structure.
5.2 Documents developed from this practice should be reviewed and revised as necessary on a two-year cycle or according to each jurisdiction’s normal practices. The review should consider new and updated requirements and guidance, technologies, and other information or equipment that might have a significant impact on the management and outcome of radiological incidents.
SCOPE
1.1 This practice provides decision-making considerations for response to both accidental and intentional incidents that involve radioactive material. It provides information and guidance for what to include in response planning and what activities to conduct during a response. It also encompasses the practices to respond to any situation complicated by radiation in conjunction with the associated guidance for the specific type of incident.
1.1.1 The intended audience for the standard includes planners as well as emergency responders, incident commanders, and other emergency workers who should be protected from radiation.
1.1.2 The scope of this practice applies to all types of radiological emergencies. While it does not fully consider response to an NPP accident,3 an explosive RDD, or nuclear detonation, detailed guidance to respond to such incidents is provided in other documents, such as those cited in the introduction. With respect to the guidance documents, this practice provides the general principles that apply to the broad range of incidents and associated planning goals but relies on the AHJ to apply and tailor their response planning based on those documents as well as the limitation of the personnel and equipment resources in the jurisdiction. In addition, the AHJ should use those documents to identify improvements to planning and resources to be better prepared for the more complex emergencies.
1.1.3 This practice does not expressly address emergency response to contamination of food or water supplies.
1.1.4 The Emergency Response Guide (ERG) published by the Department of Transportation provides valuable information for response to traffic accidents involving radioactive materials. For other radiological or nuclear incidents, however, the ERG may not provide adequate information on appropriate protective measures and should not be the sole resource used.
1.2 This practice applies to those emergency response agencies that have a role in the response to an accidental or intentional radiological or nuclear incident. It should be used by emergency response organizations such as law enforcement, fire service, emergency medical services, and emergency management.
1.3 This practice assumes that implementation begins with the recognition of a radiological or nuclear incident and ends when emergency response actions cease or the response is supported by specialized regional, state, or federal response assets.
1.4 AHJs using this practice should identify hazards, develop a plan, acquire and track equipment, and provide training consistent with the descriptions provided in Section 6.
1.5 While response to radiological hazards is the focus of this practice, responders must consider all hazards during a response; it is possible that non-radiological hazards may present a greater danger at an incident, particularly in incidents with wide area dispersion.
1.5.1 This practice does not fully address assessing the risks from airborne radioactivity. Equipment to determine this potential hazard is not widely available in emergency responder communities. Like other responses to unknown hazards, respiratory protection commonly used by responders is required until a complete hazard i...
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SCOPE
1.1 This terminology identifies and precisely defines terms as used in the standard test methods, practices, and guides for evaluating response robots intended for hazardous environments. Further discussions of the terms can be found within the standards in which the terms appear.
1.2 The term definitions address response robots, including ground, aquatic, and aerial systems. Some key features of such systems are remotely operated from safe standoff distances, deployable at operational tempos, capable of operating in complex environments, sufficiently hardened against harsh environments, reliable and field serviceable, durable or cost effectively disposable, and equipped with operational safeguards.
1.3 Units—Values stated in either the International System of Units (metric) or U.S. Customary units (inch-pound) are to be regarded separately as standard. The values stated in each system may not be exact equivalents. Both units are referenced to facilitate acquisition of materials internationally and minimize fabrication costs. Tests conducted using either system maintain repeatability and reproducibility of the test method and results are comparable.
1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
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ABSTRACT
This specification is used to standardize the portable water heaters used on personnel decontamination lines to insure the heaters provide sufficient heated water for as long as they are needed during the emergency. The heater materials of construction shall be easily cleaned of surface mud and grime with no degradation of the unit's ability to perform its function. The performance requirements for portable water heaters are presented in details. The rotometer test method, and ASTM test method shall be performed to meet the requirements prescribed. The water heater unit's water flow shall be measured, and recorded. The water heater unit's cold water inlet and warm water output temperature shall be measured and recorded. The water heater unit's water supply and outlet pressures shall be measured and recorded.
SIGNIFICANCE AND USE
12.1 The use of these acceptance tests will insure that organizations buying portable heaters will be assured the heaters meet certain performance requirements.
SCOPE
1.1 This specification is used to standardize the portable water heaters used on personnel decontamination lines to insure the heaters provide sufficient heated water for as long as they are needed during the emergency.
Note 1: These heaters are not intended to be used for the decontamination for any other surface or material. Also, these heaters are intended to be portable and easy to use by first responders during a chemical, biological, radiological, nuclear, and explosive (CBRNE) event.
1.2 This specification contains a specification section and a test methods section so users need to refer to the section applicable to their needs when using this standard specification.
1.3 The values stated in SI units are to be regarded as standard. The values given in parentheses are for information only.
Note 2: The U.S. first responder personnel using the equipment manufactured under this standard are not likely to be familiar with SI units so English units need to be included as part of the system documentation and shown on control panels for any equipment sold to U.S. organizations.
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
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ABSTRACT
This specification is used to standardize the portable air heaters used on personnel decontamination lines to insure the heaters provide sufficient heated air for personnel comfort before, during, and after the decontamination for as long as they are needed during the emergency. The heater materials of construction shall be easily cleaned of surface mud and grime with no degradation of the unit’s ability to perform its function. The preferred fuels for the heater section of the portable air heater are diesel fuel, gasoline, or bottled propane gas. Measurement of the air heater unit’s air flow and input and output temperatures shall be performed.
SIGNIFICANCE AND USE
11.1 The use of these acceptance tests will insure that organizations buying portable heaters will be assured the heaters meet certain performance requirements.
SCOPE
1.1 This specification is used to standardize the portable air heaters used on personnel decontamination lines to insure the heaters provide sufficient heated air for personnel comfort before, during, and after the decontamination for as long as they are needed during the emergency.
Note 1: These heaters are not intended to be used for the decontamination for any other surface or material. Also, these heaters are intended to be portable and easy to use by first responders during a chemical, biological, radiological, nuclear, and explosive (CBRNE) event.
1.2 This specification contains a specification section and a test methods section so users need to refer to the section applicable to their needs when using this standard specification.
1.3 The values stated in SI units are to be regarded as standard. The values given in parentheses are for information only.
Note 2: The U.S. first responder personnel using the equipment manufactured under this standard are not likely to be familiar with SI units so English units need to be included as part of the system documentation and shown on control panels for any equipment sold to U.S. organizations.
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
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SIGNIFICANCE AND USE
5.1 This test method is part of an overall suite of related test methods that provide repeatable measures of human-system interaction capability including robotic system mobility, dexterity, inspection, remote operator proficiency, and situational awareness. In particular, the operator control unit (OCU) design and interface features may impact the operator’s ability to perform movement and inspection tasks with the robot.
5.2 The test apparatuses are low cost and easy to fabricate so they can be widely replicated. The procedure is also simple to conduct. This eases comparisons across various testing locations, dates, and times to determine best-in-class systems and operators.
5.3 Evaluation—This test method can be used in a controlled environment to measure baseline capabilities. It can also be embedded into operational training scenarios to measure degradation due to uncontrolled variables in lighting, weather, radio communications, GPS accuracy, etc.
5.4 Procurement—This test method can be used to identify inherent capability trade-offs in systems, make informed purchasing decisions, and verify performance during acceptance testing. This aligns requirement specifications and user expectations with existing capability limits.
5.5 Training—This test method can be used to focus operator training, as a repeatable practice task or as an embedded task within training scenarios. The resulting measures of remote operator proficiency enable tracking of perishable skills over time, along with comparisons of performance across squads, regions, or national averages.
5.6 Innovation—This test method can be used to inspire technical innovation, demonstrate break-through capabilities, and measure the reliability of systems performing specific tasks within an overall mission sequence. Combining or sequencing multiple test methods can guide manufacturers toward implementing the combinations of capabilities necessary to perform essential mission tasks.
SCOPE
1.1 This test method is intended for remotely operated ground robots operating in complex, unstructured, and often hazardous environments. It specifies the apparatuses, procedures, and performance metrics necessary to measure the capability of a robot to maneuver and search throughout an environment to inspect objects of interest while negotiating complex terrain. This test method is one of several related human-system interaction tests that can be used to evaluate overall system capabilities.
1.2 The robotic system typically includes a remote operator in control of all functionality, so an onboard camera and remote operator display are typically required. Assistive features or autonomous behaviors may improve the effectiveness or efficiency of the overall system.
1.3 Different user communities can set their own thresholds of acceptable performance within this test method for various mission requirements.
1.4 Performing Location—This test method may be performed anywhere the specified apparatuses and environmental conditions can be implemented.
1.5 Units—The International System of Units (a.k.a. SI Units) and U.S. Customary Units (a.k.a. Imperial Units) are used throughout this test method. They are not mathematical conversions. Rather, they are approximate equivalents in each system of units to enable use of readily available materials in different countries. The differences between the stated dimensions in each system of units are insignificant for the purposes of comparing test method results, so each system of units is separately considered standard within this test method.
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
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SIGNIFICANCE AND USE
5.1 This test method is part of an overall suite of related test methods that provide repeatable measures of robotic system mobility and remote operator proficiency. The variable hurdle obstacle as described challenges robotic system locomotion, suspension systems to maintain traction, rollover tendencies, self-righting (if necessary), chassis shape variability (if available), and remote situational awareness by the operator. As such, the variable hurdle obstacle can be used to represent obstacles in the environment, such as railroad tracks, curbs, and debris.
5.2 The scale of the apparatus can vary to provide different constraints representative of typical obstacle spacing in the intended deployment environment. For example, the three configurations can be representative of repeatable complexity for unobstructed obstacles (open configuration), relatively open parking lots with spaces between cars (rectangular confinement configuration), or within bus, train, or plane aisles, or dwellings with hallways and doorways (square confinement configuration).
5.3 The test apparatuses are low cost and easy to fabricate so they can be widely replicated. The procedure is also simple to conduct. This eases comparisons across various testing locations and dates to determine best-in-class systems and operators.
5.4 Evaluation—This test method can be used in a controlled environment to measure baseline capabilities. The variable hurdle obstacle can also be embedded into operational training scenarios to measure degradation due to uncontrolled variables in lighting, weather, radio communications, GPS accuracy, etc.
5.5 Procurement—This test method can be used to identify inherent capability trade-offs in systems, make informed purchasing decisions, and verify performance during acceptance testing. This aligns requirement specifications and user expectations with existing capability limits.
5.6 Training—This test method can be used to focus operator training as a repea...
SCOPE
1.1 This test method is intended for remotely operated ground robots operating in complex, unstructured, and often hazardous environments. It specifies the apparatuses, procedures, and performance metrics necessary to measure the capability of a robot to negotiate an obstacle in the form of hurdles. This test method is one of several related mobility tests that can be used to evaluate overall system capabilities.
1.2 The robotic system includes a remote operator in control of most functionality, so an onboard camera and remote operator display are typically required. This test method can be used to evaluate assistive or autonomous behaviors intended to improve the effectiveness or efficiency of remotely operated systems.
1.3 Different user communities can set their own thresholds of acceptable performance within this test method for various mission requirements.
1.4 Performing Location—This test method may be performed anywhere the specified apparatuses and environmental conditions can be implemented.
1.5 Units—The International System of Units (a.k.a. SI Units) and U.S. Customary Units (a.k.a. Imperial Units) are used throughout this document. They are not mathematical conversions. Rather, they are approximate equivalents in each system of units to enable use of readily available materials in different countries. The differences between the stated dimensions in each system of units are insignificant for the purposes of comparing test method results, so each system of units is separately considered standard within this test method.
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
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SIGNIFICANCE AND USE
5.1 Coordination of response and recovery support cannot be performed well if the EOC team lacks an appropriate operating environment. An operating environment that increases stress in staff or hinders the ability to perform basic tasks will ultimately degrade the effectiveness of the EOC team. EOC management must be accomplished in parallel with incident management support and should be transparent to the EOC team. EOC management must also be consistent with and support the incident management system used by the EOC team (for example, the Incident Command System mandated for use in the United States under the National Incident Management System). Effective EOC management can be attributed to good preplanning and related training. This guide provides the emergency management community with practical concepts and approaches for effective EOC management.
SCOPE
1.1 This guide provides general guidelines for the management of an emergency operations center (EOC) prior to, during, and after activation for emergency or disaster support.
1.2 An EOC is where the coordination of response and recovery support is performed, but the EOC is also a physical location that generates its own demands. For the EOC team to perform effectively, the physical and organizational demands of the EOC as a facility must be met. EOC management is distinct from the operational management of the incident.
1.3 This guide may also serve as a foundation for management of a smaller facility such as a department operations center (DOC), larger facilities such as a regional operations center (ROC), or state operations center (SOC) with a broader area of responsibility and more extensive need to communicate and coordinate with others.
1.4 This guide applies to fixed facilities and does not specifically address portable or field-deployable EOCs at temporary locations, virtual EOCs using communications technology to link geographically separated participants, or EOC relocation under a Continuity of Operations Plan (COOP). However, elements within this document will apply to these situations.
1.5 This guide is the second in a series regarding the EOC. For the Standard Guide for EOC Development, see Guide E2668.
1.6 This document includes some references and terminology specific to the United States of America but may be adapted for use elsewhere.
1.7 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
1.8 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
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SIGNIFICANCE AND USE
5.1 This test method is part of an overall suite of related test methods that provide repeatable measures of robotic system mobility and remote operator proficiency. This crossing (discontinuous) pitch/roll ramp terrain specifically challenges robotic system locomotion, suspension systems to maintain traction, rollover tendencies, self-righting in complex terrain (if necessary), chassis shape variability (if available), and remote situational awareness by the operator. As such, it can be used to represent modest outdoor terrain complexity or indoor debris within confined areas.
5.2 The overall size of the terrain apparatus can vary to provide different constraints depending on the typical obstacle spacing of the intended deployment environment. For example, the terrain with containment walls can be sized to represent repeatable complexity within bus, train, or plane aisles; dwellings with hallways and doorways; relatively open parking lots with spaces between cars; or unobstructed terrains.
5.3 The test apparatuses are low cost and easy to fabricate so they can be widely replicated. The procedure is also simple to conduct. This eases comparisons across various testing locations and dates to determine best-in-class systems and operators.
5.4 Evaluation—This test method can be used in a controlled environment to measure baseline capabilities. It can also be embedded into operational training scenarios to measure degradation due to uncontrolled variables in lighting, weather, radio communications, GPS accuracy, etc.
5.5 Procurement—This test method can be used to identify inherent capability trade-offs in systems, make informed purchasing decisions, and verify performance during acceptance testing. This aligns requirement specifications and user expectations with existing capability limits.
5.6 Training—This test method can be used to focus operator training as a repeatable practice task or as an embedded task within training scenarios. The resulting mea...
SCOPE
1.1 This test method is intended for remotely operated ground robots operating in complex, unstructured, and often hazardous environments. It specifies the apparatuses, procedures, and performance metrics necessary to measure the capability of a robot to traverse complex terrains in the form of crossing (discontinuous) pitch/roll ramps. This test method is one of several related mobility tests that can be used to evaluate overall system capabilities.
1.2 The robotic system includes a remote operator in control of all functionality, so an onboard camera and remote operator display are typically required. Assistive features or autonomous behaviors that improve the effectiveness or efficiency of the overall system are encouraged.
1.3 Different user communities can set their own thresholds of acceptable performance within this test method for various mission requirements.
1.4 Performing Location—This test method may be performed anywhere the specified apparatuses and environmental conditions can be implemented.
1.5 Units—The International System of Units (SI Units) and U.S. Customary Units (Imperial Units) are used throughout this document. They are not mathematical conversions. Rather, they are approximate equivalents in each system of units to enable use of readily available materials in different countries. This avoids excessive purchasing and fabrication costs. The differences between the stated dimensions in each system of units are insignificant for the purposes of comparing test method results, so each system of units is separately considered standard within this test method.
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
1.7 This international stand...
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SIGNIFICANCE AND USE
5.1 This test method is part of an overall suite of related test methods that provide repeatable measures of robotic system mobility and remote operator proficiency. This symmetric stepfield terrain specifically challenges robotic system locomotion, suspension systems to maintain traction, rollover tendencies, self-righting in complex terrain (if necessary), chassis shape variability (if available), and remote situational awareness by the operator. As such, it can be used to represent modest outdoor terrain complexity or indoor debris within confined areas.
5.2 The overall size of the terrain apparatus can vary to provide different constraints depending on the typical obstacle spacing of the intended deployment environment. For example, the terrain with containment walls can be sized to represent repeatable complexity within bus, train, or plane aisles; dwellings with hallways and doorways; relatively open parking lots with spaces between cars; or unobstructed terrains.
5.3 The test apparatuses are low cost and easy to fabricate so they can be widely replicated. The procedure is also simple to conduct. This eases comparisons across various testing locations and dates to determine best-in-class systems and operators.
5.4 Evaluation—This test method can be used in a controlled environment to measure baseline capabilities. It can also be embedded into operational training scenarios to measure degradation due to uncontrolled variables in lighting, weather, radio communications, GPS accuracy, etc.
5.5 Procurement—This test method can be used to identify inherent capability trade-offs in systems, make informed purchasing decisions, and verify performance during acceptance testing. This aligns requirement specifications and user expectations with existing capability limits.
5.6 Training—This test method can be used to focus operator training as a repeatable practice task or as an embedded task within training scenarios. The resulting measures of remote opera...
SCOPE
1.1 This test method is intended for remotely operated ground robots operating in complex, unstructured, and often hazardous environments. It specifies the apparatuses, procedures, and performance metrics necessary to measure the capability of a robot to traverse complex terrains in the form of symmetric stepfields. This test method is one of several related mobility tests that can be used to evaluate overall system capabilities.
1.2 The robotic system includes a remote operator in control of all functionality, so an onboard camera and remote operator display are typically required. Assistive features or autonomous behaviors that improve the effectiveness or efficiency of the overall system are encouraged.
1.3 Different user communities can set their own thresholds of acceptable performance within this test method for various mission requirements.
1.4 Performing Location—This test method may be performed anywhere the specified apparatuses and environmental conditions can be implemented.
1.5 Units—The International System of Units (SI Units) and U.S. Customary Units (Imperial Units) are used throughout this document. They are not mathematical conversions. Rather, they are approximate equivalents in each system of units to enable use of readily available materials in different countries. This avoids excessive purchasing and fabrication costs. The differences between the stated dimensions in each system of units are insignificant for the purposes of comparing test method results, so each system of units is separately considered standard within this test method.
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
1.7 This international standard was developed in ...
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SIGNIFICANCE AND USE
5.1 This test method is part of an overall suite of related test methods that provide repeatable measures of robotic system mobility and remote operator proficiency. This continuous pitch/roll ramp terrain specifically challenges robotic system locomotion, suspension systems to maintain traction, rollover tendencies, self-righting in complex terrain (if necessary), chassis shape variability (if available), and remote situational awareness by the operator. As such, it can be used to represent modest outdoor terrain complexity or indoor debris within confined areas.
5.2 The overall size of the terrain apparatus can vary to provide different constraints depending on the typical obstacle spacing of the intended deployment environment. For example, the terrain with containment walls can be sized to represent repeatable complexity within bus, train, or plane aisles; dwellings with hallways and doorways; relatively open parking lots with spaces between cars; or unobstructed terrains.
5.3 The test apparatuses are low cost and easy to fabricate so they can be widely replicated. The procedure is also simple to conduct. This eases comparisons across various testing locations and dates to determine best-in-class systems and operators.
5.4 Evaluation—This test method can be used in a controlled environment to measure baseline capabilities. It can also be embedded into operational training scenarios to measure degradation due to uncontrolled variables in lighting, weather, radio communications, GPS accuracy, etc.
5.5 Procurement—This test method can be used to identify inherent capability trade-offs in systems, make informed purchasing decisions, and verify performance during acceptance testing. This aligns requirement specifications and user expectations with existing capability limits.
5.6 Training—This test method can be used to focus operator training as a repeatable practice task or as an embedded task within training scenarios. The resulting measures of remot...
SCOPE
1.1 This test method is intended for remotely operated ground robots operating in complex, unstructured, and often hazardous environments. It specifies the apparatuses, procedures, and performance metrics necessary to measure the capability of a robot to traverse complex terrains in the form of continuous pitch/roll ramps. This test method is one of several related mobility tests that can be used to evaluate overall system capabilities.
1.2 The robotic system includes a remote operator in control of all functionality, so an onboard camera and remote operator display are typically required. Assistive features or autonomous behaviors that improve the effectiveness or efficiency of the overall system are encouraged.
1.3 Different user communities can set their own thresholds of acceptable performance within this test method for various mission requirements.
1.4 Performing Location—This test method may be performed anywhere the specified apparatuses and environmental conditions can be implemented.
1.5 Units—The International System of Units (SI Units) and U.S. Customary Units (Imperial Units) are used throughout this document. They are not mathematical conversions. Rather, they are approximate equivalents in each system of units to enable use of readily available materials in different countries. This avoids excessive purchasing and fabrication costs. The differences between the stated dimensions in each system of units are insignificant for the purposes of comparing test method results, so each system of units is separately considered standard within this test method.
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.
1.7 This international standard was develo...
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- Standard10 pagesEnglish languagesale 15% off
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