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ASTM F3381-19

(Practice)

Standard Practice for Describing Stationary Obstacles Utilized within A-UGV Test Methods

Standard Practice for Describing Stationary Obstacles Utilized within A-UGV Test Methods

SIGNIFICANCE AND USE
4.1 This section lists and explains the characteristics that are used to describe a stationary obstacle.  
4.2 It is essential that sufficient information about the obstacle is recorded using this practice so that the obstacle can be replicated. This will allow comparisons to be made between test method performances that use obstacles with similar characteristics.  
4.3 Class:  
4.3.1 When describing an obstacle to be utilized in ASTM Committee F45 test methods, two classes are defined:
4.3.1.1 Genuine—The obstacle being described is an existing real world object (for example, a chair, table, machinery, or equipment). Any identifying information, such as make, model, SKU, etc., should be recorded.
4.3.1.2 Artifact—The obstacle being described has been constructed according to the characteristics outlined in this section. Obstacles of this class are intended to be replicable.  
4.4 Parts of the Obstacle:  
4.4.1 Each characteristic can be used to describe a property of the entire obstacle or a part of the obstacle. All parts of the obstacle must be uniquely named and identified in the test report described in Section 6.  
4.5 Shape:  
4.5.1 The shape refers to the relationships between the external, physical boundaries of the obstacle. All shapes can be in contact with the ground or elevated above the ground (see Fig. 1, Fig. 2, and Fig. 3). The unique obstacle shapes are:
4.5.1.1 Bar (for example, column)
4.5.1.2 Panel (for example, sign, pallet, shelf)
4.5.1.3 Cuboid
4.5.1.4 Sphere
4.5.1.5 Cone
4.5.1.6 Other—Obstacle shapes that do not fall into one of the above categories (for example, a pile of fabric). An obstacle can use a single shape to describe its overall volume or multiple shapes to describe parts of the obstacle. For example, the shape of a desk could be described as an elevated horizontal panel with two vertical panels spanning from the ground to the horizontal panel or the shape of a table could be described as an elevated hori...
SCOPE
1.1 This practice specifies physical characteristics that can be used to describe obstacles utilized within ASTM Committee F45 test methods. The obstacle characteristics specified in this practice are not described with respect to the manner in which they will be sensed or detected by an A-UGV. Rather, the obstacles are described according to their real world characteristics. For example, the real world characteristics of a wooden box that is flat black on one side can be described according to its actual dimensions, material, and color. An A-UGV with a lidar sensor may have difficulty detecting the side of the box that is flat black, which could make the obstacle appear smaller to the A-UGV compared to its actual dimensions in the real world. However, this may not be the case for other A-UGVs due to the wide variety of sensors used to detect obstacles, so the actual, real world characteristics are used to describe it instead.  
1.2 Real world, existing objects can be used as obstacles and described using this practice. The characteristics specified herein can also be used to construct test artifacts to use as representative obstacles that are intended to have similar characteristics to that of real world obstacles. The obstacles that can be described using this practice may be found in indoor and outdoor environments.  
1.3 This practice does not purport to cover all relevant obstacle characteristics that may have an effect on A-UGV performance. The characteristics specified in this practice are limited to the physical properties which are considered to be the most salient in terms of the effects they can have on A-UGV performance. As such, the user of this standard may select the level of detail to use in order to describe the characteristics of an obstacle in such a way. The characteristics are also limited to those which are more easily measurable and replicable when comparing test method results that use similar o...

General Information

Status
Published
Publication Date
30-Nov-2019
ICS
35.240.60 - IT applications in transport
43.020 - Road vehicles in general
Technical Committee
F45 - Robotics, Automation, and Autonomous Systems
Drafting Committee
F45.03 - A-UGV Object Detection and Protection
Current Stage
Ref Project

Relations

Refers
ASTM F3200-19 - Standard Terminology for Driverless Automatic Guided Industrial Vehicles
Effective Date
15-Nov-2019
Refers
ASTM F3218-17 - Standard Practice for Recording Environmental Effects for Utilization with A-UGV Test Methods
Effective Date
01-Jul-2017
Refers
ASTM F3218-19 - Standard Practice for Documenting Environmental Conditions for Utilization with A-UGV Test Methods
Effective Date
01-Sep-2019
Refers
ASTM F3200-18a - Standard Terminology for Driverless Automatic Guided Industrial Vehicles
Effective Date
01-Apr-2018
Refers
ASTM F3200-16 - Standard Terminology for Driverless Automatic Guided Industrial Vehicles
Effective Date
15-Oct-2016
Refers
ASTM F3200-17 - Standard Terminology for Driverless Automatic Guided Industrial Vehicles
Effective Date
15-May-2017
Refers
ASTM F3200-17b - Standard Terminology for Driverless Automatic Guided Industrial Vehicles
Effective Date
15-Aug-2017
Refers
ASTM F3200-17a - Standard Terminology for Driverless Automatic Guided Industrial Vehicles
Effective Date
01-Jun-2017
Refers
ASTM F3200-18 - Standard Terminology for Driverless Automatic Guided Industrial Vehicles
Effective Date
01-Feb-2018
Referred By
ASTM F3244-21 - Standard Test Method for Navigation: Defined Area
Effective Date
01-Dec-2019
Referred By
ASTM F3470-20 - Standard Guide for A-UGV Capabilities
Effective Date
01-Dec-2019
Referred By
ASTM F3588-22 - Standard Guide for Set of Objects used with A-UGVs
Effective Date
01-Dec-2019

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ASTM F3381-19 - Standard Practice for Describing Stationary Obstacles Utilized within A-UGV Test MethodsASTM F3381-19 - Standard Practice for Describing Stationary Obstacles Utilized within A-UGV Test Methods
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ASTM F3381-19 - Standard Practice for Describing Stationary Obstacles Utilized within A-UGV Test Methods
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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.
Designation: F3381 − 19
Standard Practice for
Describing Stationary Obstacles Utilized within A-UGV Test
1
Methods
This standard is issued under the fixed designation F3381; 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.
INTRODUCTION
Automatic, automated, or autonomous unmanned ground vehicles (A-UGVs) in many scenarios
encounter obstacles or objects that obstruct or impair their intended movement. This practice is used
to describe stationary objects that serve as obstacles inASTM Committee F45 test methods, both for
existing, real world obstacles and for test artifacts that can be constructed to serve as representative
obstacles.ExamplesofusingobstaclesintestmethodsincludeaddinganobstacleintotheTestMethod
F3244 – 17 apparatus or verifying a sensor’s ability to detect an obstacle. Several physical
characteristics of stationary obstacles are defined in this standard, such as geometry, surface, and
configuration. The characteristics specified herein can be used to describe common, real world
obstacles that A-UGVs typically interact with, such as pallets on the ground, desks and tables, and
otherA-UGVs. This practice only covers obstacles or objects that exist on or above the ground plane
and remain stationary while the A-UGV is performing its task.
1. Scope characteristics to that of real world obstacles. The obstacles
that can be described using this practice may be found in
1.1 This practice specifies physical characteristics that can
indoor and outdoor environments.
be used to describe obstacles utilized withinASTM Committee
F45 test methods. The obstacle characteristics specified in this
1.3 This practice does not purport to cover all relevant
practice are not described with respect to the manner in which obstacle characteristics that may have an effect on A-UGV
they will be sensed or detected by an A-UGV. Rather, the
performance. The characteristics specified in this practice are
obstacles are described according to their real world charac- limited to the physical properties which are considered to be
teristics. For example, the real world characteristics of a
the most salient in terms of the effects they can have on
wooden box that is flat black on one side can be described A-UGV performance. As such, the user of this standard may
according to its actual dimensions, material, and color. An
select the level of detail to use in order to describe the
A-UGV with a lidar sensor may have difficulty detecting the characteristics of an obstacle in such a way.The characteristics
sideoftheboxthatisflatblack,whichcouldmaketheobstacle
are also limited to those which are more easily measurable and
appear smaller to the A-UGV compared to its actual dimen- replicable when comparing test method results that use similar
sions in the real world. However, this may not be the case for
obstacles.
otherA-UGVs due to the wide variety of sensors used to detect
1.4 This practice only covers obstacles that exist on or
obstacles, so the actual, real world characteristics are used to
above the ground, sometimes referred to as positive obstacles,
describe it instead.
and remain stationary while the A-UGV is performing tasks.
1.2 Realworld,existingobjectscanbeusedasobstaclesand
Stationary real world obstacles of this type include pallets on
described using this practice. The characteristics specified
the ground, desks and tables, and otherA-UGVs. This practice
herein can also be used to construct test artifacts to use as
does not include obstacles that exist below the ground (for
representative obstacles that are intended to have similar
example, holes), sometimes referred to as negative obstacles.
This practice does not cover boundaries or features in an
environment that are unchanging and known prior to an
1
This test method is under the jurisdiction of ASTM Committee F45 on
Driverless Automatic Guided Industrial Vehicles and is the direct responsibility of A-UGV task, such as walls, racks, or other infrastructure.
Subcommittee F45.03 on Object Detection and Protection.
1.5 This practice specifies a variety of physical characteris-
Current edition approved Dec. 1, 2019. Published December 2019. DOI:
10.1520/F3381-19. tics of an obstacle, including shapes, dimensions, and surface
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
1

---------------------- Page: 1 ----------------------
F3381 − 19
qualities. Thi
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4.1 A-UGVs navigate, dock, or perform other tasks, or combinations thereof, within for example manufacturing, warehouse, hospital, and other environments. Objects (defined in Terminology F3200 as anything in the environment that is not infrastructure) and obstacles (defined in Terminology F3200 as static or moving objects that obstruct the intended movement) are common within these environments. Objects can cause A-UGV challenges in navigation, docking, etc. (see Test Method F3244, Guide F3470) where the object detection systems must provide the highest level of performance to allow safe and productive vehicle use. ASTM Committee F45 surveyed the A-UGV community of manufacturers, users, and researchers, and determined that a relatively short list of objects are the most common objects that their vehicles must detect and avoid. Additionally, ANSI/ITSDF B56.5 includes three test pieces that represent (1) the human body torso lying horizontally and (2) standing human leg, both with worst case, flat black coatings, and (3) flat objects (for example, boxes, doors, manufactured materials), including a worst case, highly (optically) reflective coating. The survey results are listed here and are considered example objects found in warehousing/manufacturing, healthcare, domestic, and retail environments:  
4.1.1 Pallets, racking, wheeled carts;  
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5.1 A-UGVs operate in a wide range of applications such as manufacturing facilities and warehouses. Fig. 1 shows three example A-UGV types and test apparatus sizes to test A-UGVs intended for different vehicle tasks, types, sizes, and capabilities. Such sites can have both defined and undefined areas that are structured and unstructured. The testing results of the candidate A-UGV shall describe, in a statistically significant way, the ability of the A-UGV to navigate through a defined area with or without impairments. Whether or not an A-UGV is able to deviate from its path, or uses features of the local environment as input to its navigation method or both, should not result in a different test method. Rather, the capabilities of the A-UGV to adapt its navigation method in a given environment will be objectively determined by its performance in the test method.  
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1.1 Purpose:  
1.1.1 The purpose of this test method is to evaluate an automatic, automated, or autonomous-unmanned ground vehicle’s (A-UGV) capability of traversing through a defined space with limited A-UGV clearance. This test method is intended for use by A-UGV manufacturers, installers, and users. This test method defines a set of generic 2D area shapes representative of user applications and for different A-UGV types.  
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5.1 This guide is intended to be used by manufacturers and users of A-UGVs: (1) to fully define capabilities of their A-UGV(s) or (2) to allow the standard requestor to describe the A-UGV capabilities required for the requested A-UGV to align with assigned task(s). A-UGVs that are covered within ASTM Committee F45 are industrial vehicles that, for example, can be automatic guided vehicles through mobile robots, can be pre-programmed-through-autonomously controlled, can operate indoors or outdoors in infinitely diverse environmental conditions and therefore, with infinitely diverse functionality. To fully describe and measure the usefulness of these vehicles, functionality can be divided into categories where associated capabilities can be independently measured. This guide therefore provides a decomposition of many, perhaps not all, categories and capabilities that are typical of current A-UGVs globally marketed.  
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4.1 This section provides a description of the environmental conditions listed in Section 1 and describes the sub-conditions within each condition. Examples provided for many of the conditions and sub-conditions are provided as guidance only. Each of the conditions described should be evaluated and documented as set forth in Sections 5, 6, and 7.  
4.2 Environmental Consistency: Static, Dynamic, Transitional:  
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FIG. 1 Example of Static Environment using Temperature
FIG. 2 Example of Static Environment using Temperature and Showing a Transition between Two Static Environments
FIG. 3 Example of Dynamic Environment using Temperature and Showing that the Environment Changed during the Test
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SIGNIFICANCE AND USE
4.1 A-UGVs navigate, dock, or perform other tasks, or combinations thereof, within for example manufacturing, warehouse, hospital, and other environments. Objects (defined in Terminology F3200 as anything in the environment that is not infrastructure) and obstacles (defined in Terminology F3200 as static or moving objects that obstruct the intended movement) are common within these environments. Objects can cause A-UGV challenges in navigation, docking, etc. (see Test Method F3244, Guide F3470) where the object detection systems must provide the highest level of performance to allow safe and productive vehicle use. ASTM Committee F45 surveyed the A-UGV community of manufacturers, users, and researchers, and determined that a relatively short list of objects are the most common objects that their vehicles must detect and avoid. Additionally, ANSI/ITSDF B56.5 includes three test pieces that represent (1) the human body torso lying horizontally and (2) standing human leg, both with worst case, flat black coatings, and (3) flat objects (for example, boxes, doors, manufactured materials), including a worst case, highly (optically) reflective coating. The survey results are listed here and are considered example objects found in warehousing/manufacturing, healthcare, domestic, and retail environments:  
4.1.1 Pallets, racking, wheeled carts;  
4.1.2 Other A-UGVs or AMRs;  
4.1.3 Steps or stairs;  
4.1.4 Tables or desks, ladders;  
4.1.5 Cables or hoses, or both;  
4.1.6 Chairs, overhangs (that is, on objects);  
4.1.7 IV poles; and  
4.1.8 Forklifts/forklift tines.
As some objects may not be cost-effectively available for only A-UGV object detection tests (for example, 4.1.2, 4.1.3, and 4.1.8), the remaining objects are potentially more cost-effective as objects and are described in this guide as the standard set of objects.  
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SCOPE
1.1 This standard guide provides a standard set of reference objects for use with automatic, automated, or autonomous unmanned ground vehicles (A-UGVs). The objects set includes typical objects found within industrial areas including, but not limited to: warehouses, hospitals, office spaces, and manufacturing facilities. Also, the objects set includes three test pieces from ANSI/ITSDF B56.5. The objects set is intended for use by A-UGV manufacturers and users to test the performance of A-UGVs when near the object(s). The objects set is minimized to include characteristics that have proven to cause interrupted A-UGV operation. Beyond this set of objects, Test Method F3418 is used to record most any object.  
1.2 The objects set contains one each of the following items: pallet, racking, ladder, cable cover, table, cart, intravenous (IV) pole, chair, forklift tines, and test pieces shown in ANSI/ITSDF B56.5, including a horizontal cylinder, vertical cylinder, and flat plate. The objects set is not intended to be exhaustive.  
1.3 It is intended that the objects set mainly includes off-the-shelf items. This standard guide provides a reporting method to provide obstacle information (for example, model, serial number, photograph) to allow obstacle use for exact replication of tests.  
1.4 The values stated in SI units are to be regarded as the standard. The values given in parentheses are not precise mathematical conversion to imperial units. They are close approximate equivalents for the purpose of specifying material dimensions or quantities that are readily available to avoid excessive fabrication costs of test apparatuses while maintaining repeatability and reproducibility of the test method results. These values given in parentheses are provided for information only and are not considered standard.  
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SIGNIFICANCE AND USE
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SCOPE
1.1 Purpose:  
1.1.1 The purpose of this test method is to evaluate an automatic, automated, or autonomous-unmanned ground vehicle’s (A-UGV) capability of traversing through a defined space with limited A-UGV clearance. This test method is intended for use by A-UGV manufacturers, installers, and users. This test method defines a set of generic 2D area shapes representative of user applications and for different A-UGV types.  
1.1.2 A-UGVs shall possess a certain set of navigation capabilities appropriate to A-UGV operations. Two examples of such capabilities include A-UGV movement between structures that define the vehicle path or obstacle avoidance. A navigation system is the monitoring and controlling functions of the A-UGV, providing frequent A-UGV updates of vehicle movement from one place to another. A-UGV environments often include various constraints to A-UGV mobility, such as boundaries and obstacles. In this test method, apparatuses, impairments, procedures, tasks, and metrics are specified that apply constraints and thereby, standard test methods for determining an A-UGV’s navigation capabilities are defined.  
1.1.3 This test method is scalable to provide a range of dimensions to constrain the A-UGV mobility during task performance.  
1.1.4 A-UGVs shall be able to handle many types of open and defined area complexities with appropriate precision and accuracy to perform a particular task.  
1.1.5 The required mobility capabilities include either preprogrammed movement, autonomous movement, or a combination of both, from a start location to an end location. Further mobility requirements may include: sustained speeds, vehicle reconfiguration to pass through defined spaces, payload, A-UGV movement within constrained volumes, A-UGV avoidance of obstacles while navigating, or other vehicle capabilities, or combinations thereof. This test method is designed such that a candidate A-UGV can be evaluated as to whe...

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ASTM
ASTM F3470-20(Guide)
Standard Guide for A-UGV Capabilities

SIGNIFICANCE AND USE
5.1 This guide is intended to be used by manufacturers and users of A-UGVs: (1) to fully define capabilities of their A-UGV(s) or (2) to allow the standard requestor to describe the A-UGV capabilities required for the requested A-UGV to align with assigned task(s). A-UGVs that are covered within ASTM Committee F45 are industrial vehicles that, for example, can be automatic guided vehicles through mobile robots, can be pre-programmed-through-autonomously controlled, can operate indoors or outdoors in infinitely diverse environmental conditions and therefore, with infinitely diverse functionality. To fully describe and measure the usefulness of these vehicles, functionality can be divided into categories where associated capabilities can be independently measured. This guide therefore provides a decomposition of many, perhaps not all, categories and capabilities that are typical of current A-UGVs globally marketed.  
5.2 Capability Categories:  
5.2.1 Goal Navigation: Pre-Programmed—Capabilities are the various abilities of the A-UGV to navigate a series of externally-defined waypoints on the way to a final goal.  
5.2.2 Goal Navigation: In situ—Capabilities are the various abilities of the A-UGV to navigate to a final goal by using the A-UGV system’s internal logic to determine the route.  
5.2.3 Localization—Capabilities are the various abilities of the A-UGV to determine its pose within an environment map.  
5.2.4 Docking—Capabilities are the various abilities of the A-UGV to stop at a position relative to another object or an absolute position in an environment.  
5.2.4.1 Infrastructure Dependence—Sub-category describing the need of the A-UGV to rely on features in the environment for Goal Navigation: Pre-Programmed, Goal Navigation: In-Situ, Localization, or Docking.  
5.2.5 Obstacle Avoidance: Single Vehicle—Capabilities are the various abilities of the A-UGV not to collide with an obstacle(s).  
5.2.5.1 Types of objects that can be avoided and are with...
SCOPE
1.1 This guide categorizes the autonomous capabilities of an automatic through autonomous-unmanned ground vehicle (A-UGV) based on the following list of capability categories:
(a) Goal Navigation: Pre-Programmed;
(b) Goal Navigation: In situ;
(c) Localization;  
(d) Docking—Infrastructure Dependence;
(e) Obstacle Avoidance—Types of objects that can be avoided and are within the A-UGV envelope, and types of objects that can be avoided and are outside of the A-UGV envelope;
(f) Changing Contour Area or Envelope;
(g) Changing Payload;  
(h) Impaired Communication Behavior;  
(i) Lost Communication Behavior;  
(j) Environmental Conditions;
(k) Fleet Makeup—Fleet Task Assignment, Information Sharing/Updating, Fleet Navigation Coordination, and Fleet Task Coordination.  
1.2 This guide provides a basis for A-UGV manufacturers and users to compare the intended task to the A-UGV capability. This guide does not purport to cover all relevant capabilities or categories that an A-UGV can perform. Instead, this guide provides a method for defining A-UGV capabilities and limits of A-UGV capabilities within specified categories listed in 1.1.  
1.3 One or more capabilities may be used to define the A-UGV capability and not all categories are required to be used for defining the capability of an A-UGV.  
1.4 The values stated in SI units are to be regarded as the standard. The values given in parentheses are not precise mathematical conversions to imperial units. They are close approximate equivalents for the purpose of specifying material dimensions or quantities that are readily available to avoid excessive fabrication costs of test apparatuses while maintaining repeatability and reproducibility of the test method results. These values given in parentheses are provided for information only and are not considered standard.  
1.5 This standard does not purport to address all of the safety concerns, if any, associat...

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ASTM
ASTM F3218-19(Practice)
Standard Practice for Documenting Environmental Conditions for Utilization with A-UGV Test Methods

SIGNIFICANCE AND USE
4.1 This section provides a description of the environmental conditions listed in Section 1 and describes the sub-conditions within each condition. Examples provided for many of the conditions and sub-conditions are provided as guidance only. Each of the conditions described should be evaluated and documented as set forth in Sections 5, 6, and 7.  
4.2 Environmental Consistency: Static, Dynamic, Transitional:  
4.2.1 Static is when the environment is similar throughout the test apparatus. For example, there are minor fluctuations in temperature throughout the apparatus as shown in Fig. 1 and Fig. 2. Dynamic is when the environment significantly differs within the test apparatus. For example, when the temperature changes between repetitions as shown in Fig. 3. Transitional is when the environment significantly differs in different areas within the test apparatus as shown in Fig. 4. The intent here is to not give specific guidance, but to provide a high-level classification of a particular set of environmental conditions. If environment consistency is dynamic or transitional, or both, a report form (see Section 7) for each unique set of environmental conditions should be completed.
FIG. 1 Example of Static Environment using Temperature
FIG. 2 Example of Static Environment using Temperature and Showing a Transition between Two Static Environments
FIG. 3 Example of Dynamic Environment using Temperature and Showing that the Environment Changed during the Test
FIG. 4 Example of Transitional Environment using Temperature; Portions of the Environment May Remain Static or May Be Dynamic (for example, Cold to Colder)  
4.3 Lighting:  
4.3.1 Various lighting conditions can potentially affect A-UGV optical sensor performance by affecting sensor and in turn, A-UGV responsiveness. Lighting sources can include ambient lighting as well as light emitters associated A-UGV operation. Two setups for lighting include direct or ambient source(s) applied to the A-UGV. Direct...
SCOPE
1.1 When conducting test methods, it is important to consider the role that the environmental conditions play in the Automatic through Autonomous – Unmanned Ground Vehicle (A-UGV) performance. Various A-UGVs are designed to be operated both indoors and outdoors under conditions specified by the manufacturer. Likewise, end users of the A-UGV will be operating these vehicles in a variety of environmental conditions. When conducting and replicating F45 test methods by vehicle manufacturers and users, it is important to specify and document the environmental conditions under which the A-UGV is to be tested as there will be variations in vehicle performance caused by the conditions, especially when comparing and replicating sets of test results. It is also important to consider changes in environmental conditions during the course of operations (for example, transitions between conditions). As such, environmental conditions specified in this practice are static, dynamic, or transitional, or combinations thereof; with the A-UGV stationary or in motion. This practice provides brief introduction to the following list of environmental conditions that can affect performance of the A-UGV: Lighting, External sensor emission, Temperature, Humidity, Electrical Interference, Air quality, Ground Surface, and Boundaries. This practice then breaks down each condition into sub-categories so that the user can document the various aspects associated with the category prior to A-UGV tests defined in ASTM F45 Test Methods (for example, F3244). It is recommended that salient environment conditions be documented when conducting F45 test methods.  
1.2 The environmental conditions listed in 1.1 to be documented for A-UGV(s) being tested are described and parameterized in Section 4 and allow a basis for performance comparison in test methods. The approach is to divide the list of environmental conditions into sub-conditions that represent the var...

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ASTM
ASTM A370-23(Test Method)
Standard Test Methods and Definitions for Mechanical Testing of Steel Products

SIGNIFICANCE AND USE
4.1 The primary use of these test methods is testing to determine the specified mechanical properties of steel, stainless steel, and related alloy products for the evaluation of conformance of such products to a material specification under the jurisdiction of ASTM Committee A01 and its subcommittees as designated by a purchaser in a purchase order or contract.  
4.1.1 These test methods may be and are used by other ASTM Committees and other standards writing bodies for the purpose of conformance testing.  
4.1.2 The material condition at the time of testing, sampling frequency, specimen location and orientation, reporting requirements, and other test parameters are contained in the pertinent material specification or in a general requirement specification for the particular product form.  
4.1.3 Some material specifications require the use of additional test methods not described herein; in such cases, the required test method is described in that material specification or by reference to another appropriate test method standard.  
4.2 These test methods are also suitable to be used for testing of steel, stainless steel and related alloy materials for other purposes, such as incoming material acceptance testing by the purchaser or evaluation of components after service exposure.  
4.2.1 As with any mechanical testing, deviations from either specification limits or expected as-manufactured properties can occur for valid reasons besides deficiency of the original as-fabricated product. These reasons include, but are not limited to: subsequent service degradation from environmental exposure (for example, temperature, corrosion); static or cyclic service stress effects, mechanically-induced damage, material inhomogeneity, anisotropic structure, natural aging of select alloys, further processing not included in the specification, sampling limitations, and measuring equipment calibration uncertainty. There is statistical variation in all aspects of mechanical testin...
SCOPE
1.1 These test methods2 cover procedures and definitions for the mechanical testing of steels, stainless steels, and related alloys. The various mechanical tests herein described are used to determine properties required in the product specifications. Variations in testing methods are to be avoided, and standard methods of testing are to be followed to obtain reproducible and comparable results. In those cases in which the testing requirements for certain products are unique or at variance with these general procedures, the product specification testing requirements shall control.  
1.2 The following mechanical tests are described:    
Sections  
Tension  
7 to 14  
Bend  
15  
Hardness  
16  
Brinell  
17  
Rockwell  
18  
Portable  
19  
Impact  
20 to 30  
Keywords  
32  
1.3 Annexes covering details peculiar to certain products are appended to these test methods as follows:    
Annex  
Bar Products  
Annex A1  
Tubular Products  
Annex A2  
Fasteners  
Annex A3  
Round Wire Products  
Annex A4  
Significance of Notched-Bar Impact Testing  
Annex A5  
Converting Percentage Elongation of Round Specimens to
Equivalents for Flat Specimens  
Annex A6    
Testing Multi-Wire Strand  
Annex A7  
Rounding of Test Data  
Annex A8  
Methods for Testing Steel Reinforcing Bars  
Annex A9  
Procedure for Use and Control of Heat-cycle Simulation  
Annex A10  
1.4 The values stated in inch-pound units are to be regarded as standard. The values given in parentheses are mathematical conversions to SI units that are provided for information only and are not considered standard.  
1.5 When these test methods are referenced in a metric product specification, the yield and tensile values may be determined in inch-pound (ksi) units then converted into SI (MPa) units. The elongation determined in inch-pound gauge lengths of 2 in. or 8 in. may be report...

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ASTM
ASTM D3495-10(2023)(Test Method)
Standard Test Method for Hexane Extraction of Leather

SIGNIFICANCE AND USE
3.1 This test method measures the amount of hexane-soluble lubricant present in all types of leather. Adequate lubrication prevents abrasion of leather fibers during flexing. This lubrication is generally obtained from the fat liquor added at the tannery. Some lubrication is also obtained from natural grease produced during the life of the animal.
SCOPE
1.1 This test method covers the quantitative extraction of all types of leather with hexane. This test method does not apply to wet blue.  
1.2 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.3 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.  
1.4 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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