Required skills

Required skills include

applying advanced scientific principles relevant to avionic engineering

analysing the given situation to determine what is required in the manner of a solution

analysing the given situation to determine which avionic scientific principles are selected

selecting appropriate avionic techniques and associated technologies software and hardware to suit the applications

applying appropriate avionic principles in determining the required solution

applying and manipulating formulas and calculations for engineering applications

using the correct units to solve engineering calculations

checking the validity of equations using a systematic method for ensuring coherent units

applying avionic techniques and associated technologies software and hardware in a manner appropriate to the application and identified scientific principles

referring solutions to the original aim of the application

quoting solutions in appropriate units and using appropriate significant figures

presenting solutions referring to the original aim of the application

Required knowledge

Required knowledge includes

physics analysis and application of

linear kinematics

planar kinematics

Newtons Laws of Motion

friction

momentum and center of gravity

gravity

circular motion

orbital motion

rotational motion

oscillation

electronic fundamentals determination of required values and characteristics for

resistors including light and voltage dependent resistors

capacitors

inductors

transformers

diodes

transistors

power amplifiers

oscillators

silicon controlled rectifiers

thyristor power control circuits

optocouplers

selection of appropriate test equipment

digital electronics design construction and testing of

clocked sequential circuits

registers

oscillators

timers

interfacing circuits

program logic array

state machines

data communications analysis and application of

selection of data transmission methods

universal asynchronous receiver transmitter construction

multiplexers and demultiplexers

data encryptiondecryption theory

electronic circuit analysis involving the application of

Fourier Transforms

Laplace Transforms

aerodynamics application of

drag and speed

powerthrust available and powerthrust required

manoeuvering flight

stability and control

strength of materials application of

bending and shear in beams

forces in trusses and frames

engineering concepts of stress and strain

properties of areas

torsion

mechanical properties of materials

two dimensional stress and strain including elastic constants

computer softwareprogramming application of

high level languages

algorithm design and testing

Pascal and TurboPascal programming

the limitations of avionic techniques and associated technologies software and hardware

the procedure for ensuring coherent units for meaningful solutions to equations

the concept of significant figures

the uncertainty of computations based on experimental data

the procedures for determining the significance of figures in calculations

the procedures for estimating errors in derived quantities

the method of application of the avionic techniques and associated technologies software and hardware

the application of the calculation solution style

the significance of the noncalculation solution style

The evidence guide provides advice on assessment and must be read in conjunction with the performance criteria required skills and knowledge range statement and the Assessment Guidelines for the Training Package

Overview of assessment

Evidence should be provided through the application of scientific principles and techniques in a range of avionic engineering situations

Critical aspects for assessment and evidence required to demonstrate competency in this unit

Assessors should ensure that candidates can

consistently select and apply appropriate scientific principles in avionic engineering situations

document in an appropriate style the solutions obtained through the application of chosen scientific principles in avionic engineering situations

Context of and specific resources for assessment

Assessment may occur on the job or in an appropriately simulated environment Access is required to real or appropriately simulated situations including work areas materials and equipment and to information on workplace practices and work health and safety WHS and environment practices

Where applicable reasonable adjustment must be made to work environments and training situations to accommodate ethnicity age gender demographics and disability

Access must be provided to appropriate learning andor assessment support when required Where applicable physical resources should include equipment modified for people with disabilities

Method of assessment

Assessment must satisfy the endorsed Assessment Guidelines of the MEM Metal and Engineering Training Package

Assessment must satisfy the endorsed Assessment Guidelines of the MEM05 Metal and Engineering Training Package.

Assessment methods must confirm consistency and accuracy of performance over time and in a range of workplace relevant contexts together with application of underpinning knowledge

Assessment methods must be by direct observation of tasks and include questioning on underpinning knowledge to ensure its correct interpretation and application

Assessment may be applied under projectrelated conditions real or simulated and require evidence of process

Assessment must confirm a reasonable inference that competency is not only able to be satisfied under the particular circumstance but is able to be transferred to other circumstances

Assessment may be in conjunction with assessment of other units of competency where required

Guidance information for assessment

Assessment processes and techniques must be culturally appropriate and appropriate to the language and literacy capacity of the candidate and the work being performed

Sources of information

Avionic engineering

Avionic engineering applications