IEEE 511 1979

$26.54

IEEE Standard on Video Signal Transmission Measurement of Linear Waveform Distortion

Published By	Publication Date	Number of Pages
IEEE	1979	33

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Description

New IEEE Standard – Inactive – Withdrawn. Withdrawn Standard. This standard describes methods for measuring the linear waveform distortions of TV video signals, that is, distortions which are caused by amplitude-independent (linear) transmission characteristics of television equipment and facilities. The primary application of this standard is for routine operational and maintenance tests, where rapid interpretation of test results is desirable. The techniques described here may also be applicable to laboratory measurements, and detailed mainteance procedures.

PDF Catalog

PDF Pages	PDF Title
8	1 Scope 2 Definitions 2.1 GeneralTerms
9	Terms for Waveform Test Signals in TV System M 2T Pulse T Pulse and T Step with T Step Rise and Fall
10	2.3 Discussion 3 Requirements for Measurements 3.1 TheTest Si gnal
11	Modulated 12.5T Pulse Envelope of Frequency Spectrum of Modulated 12.5T Pulse TheWindowSi gnal
12	3.2 TheOscilloscope Special Measuring Techniques 4 The Measurement of Linear Waveform Distortions 4.1 General 4.2 Field-Time Waveform Distortion A Suitable Test Signal for Measuring Linear Waveform Distortions
13	4.3 Line-Time Waveform Distortion 4.4 Short-Time Waveform Distortion Field-Time Waveform Distortion (FD) Line-Time Waveform Distortion (LD)
14	T Pulse Response 4.6 Linear Chrominance Distortion Short-Time Waveform Distortion (SD)
15	Ringing; B-SD = 2 Percent Overshoot; C-SD = 4 Percent Undershoot
16	T Pulse Response (TPR) Chrominance Time (RCT)
18	The Sin2 Pulse and the Sin2 Step A1 Description and Derivation of a T Pulse A2 Description and Derivation of a T Step
19	A3 The Frequency Function of a T Pulse T Pulse and T Step FigA2 Trainof TPulses
20	A4 The Frequency Function of a Line Bar with T Step and TStep Train of Line Bars with T Step
21	Relative to Pulse or Bar Amplitude
22	The Measurement of Short-Time Waveform Distortion Appendix B B1 Comparison of Existing T Step Tolerance Limits MJapan(4MHz) B(5MHz) M Japan and B on Normalized Time Scale
23	B2 A Graticule for Short-Time Waveform Distortion in System M Amplitude Weighting for Short-Time Waveform Distortion Tolerance Limits for Short-Time Waveform Distortion System M
24	B3 How to Determine the SD without the Aid of an Oscilloscope Graticule Short-Time Waveform Distortion (SD) Determined with Graticule Typical Examples of SD Determined with Graticule
25	Short-Time Waveform Distortion SD), Determined Arithmetically
26	B4 Mathematical Analysis of SD Tolerance Limits Typical Examples of SD Determined Arithmetically
28	The Measurement of Linear Chrominance Distortion Appendix C C1 The Modulated 12.5T Pulse Modulated 12.5T Pulse Envelope of Frequency Spectrum of MOD 12.5T Pulse
29	C2 Linear Chrominance Distortion C3 Relative Chrominance Level (RCL) C4 Relative Chrominance Time (RCT) C5 RCT Present Together with RCL Relative Chrominance Level (RCL) Relative Chrominance Time (RCT)
30	Together
31	RCT as a Function of the Baseline Sinusoid of the Mod 12.5T Pulse
32	C7 The Amplitude of the MOD 12.5T Pulse as a Function of RCT
33	Appendix D Bibliography