Search Results

Standard

Verification Methods for MIL-STD-1760E Aircraft Station Interfaces

2017-03-30

CURRENT

AS47643

This document establishes techniques for validating that an Aircraft Station Interface (ASI) complies with the interface requirements delineated in MIL-STD-1760 Revision E.

Standard

Validation Methods for MIL-STD-1760C Aircraft Station Interfaces

2004-06-17

HISTORICAL

AS47642

This document establishes techniques for validating that an Aircraft Station Interface (ASI) complies with the interface requirements delineated in MIL-STD-1760C. For validation of aircraft designed to MIL-STD-1760A Notice 2 AS4764 Issued 1995-04 applies. For validation of aircraft designed to MIL-STD-1760B Notice 3 AS47641 Issued 1999-08 applies.

Standard

Validation Methods for MIL-STD-1760C Aircraft Station Interfaces

2012-07-12

HISTORICAL

AS47642A

This document establishes techniques for validating that an Aircraft Station Interface (ASI) complies with the interface requirements delineated in MIL-STD-1760C. For validation of aircraft designed to MIL-STD-1760A Notice 2 AS4764 Issued 1995-04 applies. For validation of aircraft designed to MIL-STD-1760B Notice 3 AS47641 Issued 1999-08 applies.

Standard

Validation Methods for MIL-STD-1760C Aircraft Station Interfaces

2017-06-28

CURRENT

AS47642B

This document establishes techniques for validating that an Aircraft Station Interface (ASI) complies with the interface requirements delineated in MIL-STD-1760C. For validation of aircraft designed to MIL-STD-1760A Notice 2 AS4764 Issued 1995-04 applies. For validation of aircraft designed to MIL-STD-1760B Notice 3 AS47641 Issued 1999-08 applies.

Standard

Validation Methods for MIL-STD-1760B Aircraft Station Interfaces

2012-07-12

HISTORICAL

AS47641

This document establishes techniques for validating that an Aircraft Station Interface (ASI) complies with the interface requirements delineated in MIL-STD-1760B Notice 3. For validation of aircraft designed to MIL-STD-1760A Notice 2 AS4764 Issued 1995-04 applies.

Standard

Validation Methods for MIL-STD-1760B Aircraft Station Interfaces

2017-06-28

CURRENT

AS47641A

This document establishes techniques for validating that an Aircraft Station Interface (ASI) complies with the interface requirements delineated in MIL-STD-1760B Notice 3. For validation of aircraft designed to MIL-STD-1760A Notice 2 AS4764 Issued 1995-04 applies.

Standard

Validation Methods for MIL-STD-1760 Mission Stores

2012-07-12

HISTORICAL

AS4270

This document establishes techniques for validating that a mission store complies with the interface requirements delineated in MIL-STD-1760.

Standard

Validation Methods for MIL-STD-1760 Mission Stores

2017-06-27

CURRENT

AS4270A

This document establishes techniques for validating that a mission store complies with the interface requirements delineated in MIL-STD-1760.

Standard

Validation Methods for MIL-STD-1760 Aircraft Station Interfaces

2012-07-31

HISTORICAL

AS4764

This document establishes techniques for validating that an aircraft station complies with the interface requirements delineated in MIL-STD-1760.

Standard

Validation Methods for MIL-STD-1760 Aircraft Station Interfaces

2017-06-27

CURRENT

AS4764A

This document establishes techniques for validating that an aircraft station complies with the interface requirements delineated in MIL-STD-1760.

Standard

Technical Architecture for Aircraft, Launcher, and Weapon Interoperability (ALWI TA)

2012-08-27

CURRENT

AIR5720A

The technical architecture defined in this document outlines mandatory, emerging, and needed standards to provide interoperability at key interfaces in the aircraft/store system (including an associated NATO Network Enabled Capability environment), as required to support a future plug-and-play aircraft/store integration capability. These standards relate to services and protocols associated with the subject interfaces. Modeling standards to facilitate the Model Driven Architecture® (MDA®) approach to system definition and implementation are also included. Note that the status of referenced standards as reflected in this document is as of August 2007, and document users should check to see if there has been a subsequent change of status relative to applicable standards.

Standard

Technical Architecture for Aircraft, Launcher, and Weapon Interoperability (ALWI TA)

2008-01-16

HISTORICAL

AIR5720

The technical architecture defined in this document outlines mandatory, emerging, and needed standards to provide interoperability at key interfaces in the aircraft/store system (including an associated NATO Network Enabled Capability environment), as required to support a future plug-and-play aircraft/store integration capability. These standards relate to services and protocols associated with the subject interfaces. Modeling standards to facilitate the Model Driven Architecture® (MDA®) approach to system definition and implementation are also included. Note that the status of referenced standards as reflected in this document is as of August 2007, and document users should check to see if there has been a subsequent change of status relative to applicable standards.

Standard

Standard Electrical and Logical Interface for Airborne Fuzing Systems

2012-12-03

CURRENT

AS5716A

This interface standard applies to fuzes/fuzing systems (referred to as fuzing system hereafter) in airborne weapons that use a MIL-STD-1760 type interface. It defines the powers, the discrete signals and the serial data interface for the communications at the interface between the fuzing system and the remainder of the weapon, including the weapon control unit. The Class 1 interface is an electrical only interface that facilitates use of MIL-STD-1760 type platform store interfaces for the fuze to monitor intentional release and defines the fuze interface bus communications protocol to allow sending and receiving data from fuzing systems. Class 2 interfaces add a defined connector and additional interfaces to facilitate the exchange of compatible fuzing systems. Class 3 interfaces add further interface definitions to facilitate the exchange of AS5680A compatible fuzing systems components.

Standard

Interface Standard, Miniature Mission Store Interface

2008-01-08

HISTORICAL

AS5725

This standard defines implementation requirements for the electrical interface between: a aircraft carried miniature store carriage systems and miniature stores b aircraft parent carriage and miniature stores c surface based launch systems and miniature stores The interface provides a common interfacing capability for the initialization and employment of smart miniature munitions and other miniature stores from the host systems. Physical, electrical, and logical (functional) aspects of the interface are addressed.

Standard

Interface Standard, Miniature Mission Store Interface

2015-12-19

HISTORICAL

AS5725B

This standard defines implementation requirements for the electrical interface between: a aircraft carried miniature store carriage systems and miniature stores b aircraft parent carriage and miniature stores c surface based launch systems and miniature stores The interface provides a common interfacing capability for the initialization and employment of smart miniature munitions and other miniature stores from the host systems. Physical, electrical, and logical (functional) aspects of the interface are addressed.

Standard

Interface Standard, Miniature Mission Store Interface

2011-05-24

HISTORICAL

AS5725A

This standard defines implementation requirements for the electrical interface between: a aircraft carried miniature store carriage systems and miniature stores b aircraft parent carriage and miniature stores c surface based launch systems and miniature stores The interface provides a common interfacing capability for the initialization and employment of smart miniature munitions and other miniature stores from the host systems. Physical, electrical, and logical (functional) aspects of the interface are addressed.

Standard

Interface Standard, Common Interface Control Plan

2016-01-02

CURRENT

AS6030A

This Common Interface Control Plan (CICP) establishes the methodology for developing, controlling, and managing the technical interfaces between and within systems. An interface defines the interaction at a defined point between entities to achieve a combined system capability. A common interface defines the shared interaction between multiple systems on either side of the interface. The document is not intended to directly control any other aspects of program management, such as matters of contractual, financial, or those of an intellectual property rights nature. Members in the interface control process include: procurement authorities, design authorities, and other related agencies as defined in the specific System Interface Control Plan (SICP). For the purposes of this plan, only the terms Procuring Organization and Producing Organization will be used.

Standard

Interface Standard, Common Interface Control Plan

2011-01-03

HISTORICAL

AS6030

This Common Interface Control Plan (CICP) establishes the methodology for developing, controlling and managing the technical interfaces between and within systems. The document is not intended to directly control any other aspects of program management, such as matters of contractual, financial or those of an intellectual property rights nature. Members in the interface control process include: procurement authorities, design authorities and other related agencies as defined in the specific System Interface Control Plan (SICP). For the purposes of this plan only the terms Procuring Organization and Producing Organization will be used.

Standard

Handbook: Standard Electrical and Logical Interface for Airborne Fuzing Systems

2016-11-18

CURRENT

AIR6234

This Handbook is intended to provide useful information on the application of AS5716A. It is for use by System Program Offices, aircraft prime contractors, avionics and store system designers, system integrators and equipment manufacturers and users. This Handbook was prepared to provide users of the standard of the rationale and principles considered during the development of the standard. It is anticipated that the handbook will serve to assist developers in introducing new technology to achieve compliance with the standard and the underlying principles of the standard. It is intended that the Handbook be used alongside the standard, as it does not contain significant extracts of the standard.

Standard

Fuze Well Mechanical Interface

2019-09-03

CURRENT

AS5680B

This interface standard applies to fuzes used in airborne weapons that use a 3-in fuze well. It defines: Physical envelope of the fuze well at the interface with the fuze. Load bearing surfaces of the fuze well. Physical envelope of the fuze and its connector. Mechanical features (e.g., clocking feature). Connector type, size, location and orientation. Retaining ring and its mechanical features (e.g., thread, tool interface). Physical envelope of the retaining ring at the interface with the fuze. Physical space available for installation tools. Torque that the installation tool shall be capable of providing. This standard does not address: Materials used or their properties. Protective finish. Physical environment of the weapon. Explosive interface or features (e.g., insensitive munitions (IM) mitigation). Charging tube. Torque on the retaining ring or loads on the load bearing surfaces.