ARP-4761 Training

ARP-4761 training provides you with the strategies and techniques to execute safety analysis. Such strategy is relevant with demonstrating compliance with certification criteria (14CFR/CS Parts 23 and 25, section 1309) and helping an organization to fulfill their own unique safety guidelines. The safety procedures explained are mainly relevant with civil avionic gear but the procedures and techniques might be used in several cases.

ARP-4761 Training covers the standard data to perform the industry approved safety analysis including Functional Hazard Assessment (FHA), Preliminary System Safety Assessment (PSSA), and System Safety Assessment (SSA). We will discuss different safety evaluation techniques required to implement and perform the safety analysis. We also will teach you various safety evaluation techniques consisting of Fault Tree Analysis (FTA), Dependence Diagram (DD), Markov Analysis (MA), Failure Modes and Effect Analysis (FMEA) and Common Cause Analysis (CCA). CCA is comprised of Zonal Safety Analysis (ZSA), Particular Risks Analysis (PRA), and Common Mode Analysis (CMA).

ARP-4761 Training teaches you the Safety Assessment Process in avionic systems, as well as incorporating it with other execution procedures. We will discuss the essence of the Reliability Theory and its relevance to airborne systems, equipment specifications and that how they are applied during both the initial and final system safety assessment process.

ARP-4761 training course also considers each of the tools and techniques for performing the Safety Assessment Process, containing real-world scenarios for each of the fundamental methods. We will elaborate precisely how the regulatory structure works and how ARP-4761 fits in. We also explain how ARP-4761 corresponds to other standards for civil airborne systems and equipment, in particular with ARP-4754A.

ARP-4761 TrainingDuration: 2 days

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CUSTOMIZE It
  • We can adapt this ARP-4761 Training course to your group’s background and work requirements at little to no added cost.
  • If you are familiar with some aspects of this ARP-4761 Training course, we can omit or shorten their discussion.
  • We can adjust the emphasis placed on the various topics or build the ARP-4761 Training course around the mix of technologies of interest to you (including technologies other than those included in this outline).
  • If your background is nontechnical, we can exclude the more technical topics, include the topics that may be of special interest to you (e.g., as a manager or policy-maker), and present the ARP-4761 Training course in manner understandable to lay audiences.
AUDIENCE/TARGET GROUP

The target audience for this ARP-4761 Training course:

  • Engineers and professionals
  • Safety officers and managers
  • Quality managers
  • Project engineers
  • Safety engineers
  • Software/hardware engineers
  • Quality assurance or certification personnel
CLASS PREREQUISITES

The knowledge and skills that a learner must have before attending this ARP-4761 Training course are:

  • N/A
ARP-4761 Training - OBJECTIVES

Upon completing this ARP-4761 Training course, learners will be able to meet these objectives:

  • Recognize several safety analysis techniques
  • Relate the main participants of ARP-4761 FHA, PSSA, SSA, FTA, DD, MA, CCA
  • Recognize the use of safety methods
  • Determine the communication among the safety procedures and the development procedures
  • Use several safety tools in implementation of a PSSA or SSA
  • Analyze potential methods for presence in ARP-4761
  • Comprehend the procedures necessary for the development of civil aerial systems and technology
  • Deliver comprehensive goals that must be fulfilled by the systems development procedure
  • Explain the overall rules and that how they are used to identify DALs
  • Employ the verification and validation methods as part of the system development procedure
  • Employ the new standard material inside their own organizational framework
  • Describe the avionic systems development procedure and its association with the safety analysis procedure
  • Determine the main avionic systems development procedures and their interrelationships
ARP-4761 Training - COURSE SYLLABUS
Overview of ARP-4761
  • ARP-4761 description
  • Terminology
  • History and background
  • Methods and tools
  • Best practices
  • Life cycle
  • System Safety Assessment Process
  • Faults, Errors, and Failures
  • Basic definitions
  • Development & certification process
Model-Based Safety Analysis Process
  • Model-based development
  • Model-based safety assessment
  • Nominal system modeling
    • Validating consequent safety criteria
    • Fault modeling
    • Model extension
    • Safety assessment simulation
    • Proofs of safety specifications
    • Fault trees
ARP-4761 Methods
  • Functional Hazard Assessment (FHA)
  • Preliminary System Safety Analysis (PSSA)
  • Fault Tree Analysis (FTA)
  • Dependency Diagram (DD)
  • Markov Analysis (MA)
  • Failure Modes & Effects Analysis (FMEA)
  • Common Cause Analysis (CCA)
  • Particular Risks Analysis (PRA)
  • Zonal Safety Analysis (ZSA)
  • Common Mode Analysis (CMA)
  • System Safety Analysis (SSA)
Safety Life Cycle
  • Executing the aircraft level FHA while developing the aircraft level criteria
  • Implementing the system level FHA along with with distribution of aircraft operations to system operations, and begin the CCA
  • Conducting the PSSA align with system structure development, and renew the CCA
  • Repeating the CCA and PSSA as the system is apportioned into hardware and software elements
  • Conducting the SSA in line with system execution, and completing the CCA
  • Supplying the outcomes of the previous steps into the certification process
Development Assurance Levels
  • Level A
    • Extremely Improbable
  • Level B
    • Extremely Remote
  • Level C
    • Remote
  • Level D
    • Reasonably Probable, frequent
Workshop: The Wheel Brake System

The Wheel Brake System is installed on the two primary landing tools. Braking on the major apparatus wheels is applied to give support to safe impedance of the airplane during the taxi and landing phases, and also in the case of a rejected take-off. A secondary role of the wheel brake system is to stop the main gear wheel rotation upon gear withdrawal.

Such braking system can be conducted both commanded manually, via brake pedals, or automatically (auto-brake) with no need for pedal use. The auto-brake operation helps the pilot to pre-equip the braking rate before takeoff or landing. When the wheels have traction, the auto-brake operation will regulate the pressure necessary for brake to smooth the deceleration.

Based on the ARP-4761 guideline, discuss:

  • Nominal system modeling
    • Braking System Control Unit (BSCU)
    • Hydraulic pressure pumps
    • Isolation valves
    • Selector valve
    • Accumulator valve
    • Meter valves
  • Validating the derived safety criteria
  • Fault modeling and extension
    • Digital fault modeling
    • Mechanical fault modeling
    • Fault modeling and extension issues
  • Official safety assessment
    • Fault tolerance verification via model-checkers
    • Official safety assessment issues
    • Projected method for fault tree initiation by PVS
  • Present the final results

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