Tektronix DTG5000 Series User Manual

HDMI Compliance & Sink Characterization Using DTG5000 Series Data Timing Generator

Application Note

11

www.tektronix.com/signal_sources

Software Tools For Sink Tests

Sink tests, like Source tests, can take a lot of time. In

case of Sink tests, there is the complexity of controlling

several tools to conclude a measurement, as well as

the challenge of precisely setting jitter parameters.

All this makes automation an implicit requirement.

The TDSHT3 application package described earlier

is optimized to speed HDMI testing and compliance

work. TDSHT3 makes uses the GPIB interface to

remotely control various parameters. The oscilloscope

connects to the DTG5000 Series using a GPIB cable

and to the AWG or arbitrary function generator using

a GPIB-USB-B cable or E-Net to GPIB converter

(available from National Instruments).

Many HDMI test setups and measurements reside

within the TDSHT3 application; others can be down-

loaded at www.tek.com. Table 4 lists the standard

setups, and the CTS tests to which they apply.

Testing HDMI Cables

HDMI cables can be characterized in either or both of

two ways: time-domain reflectometry (TDR) and eye

diagram testing. The TDR technique uses a digital

sampling oscilloscope to measure the impedance

characteristics of a cable with great precision, but

cannot verify waveform quality.

Eye diagram testing involves displaying a waveform

that consists of rising and falling edges superimposed

in such a way that there is an “eye” opening bounded

on all sides by positive-going and negative-going

transitions. Typically there is a region within this

opening that must not be violated by any waveform

data point. To do so would indicate insufficient

signal amplitude, slow rise or fall times, jitter, or a

combination of these aberrations.

The DTG5000 Series can produce standard HDMI

signals for use as test data in eye diagram mask

testing to reveal the true waveform performance of

the cable. First, transmitter performance can be

verified by inserting the test data signals ahead of the

transmitter and performing the eye mask test at the

transmitter output. Once this is confirmed, the test

data signals can be inserted at the beginning of the

cable and eye mask testing performed with the

TDSHT3 package at the end. If jitter violates the

eye mask, the cable has insufficient bandwidth. If

the signals have insufficient level, the cable loss is

too high. Figure 10 is an eye diagram captured by

the TDSHT3 application software package.

Conclusion

Compliance testing of HDMI Sink devices is no longer

limited to the use of custom data sources and tedious

manual methods. The DTG5000 Series high perform-

ance data generators solve the problem by providing

a full complement of highly accurate data signals with

precise control over the signal parameters. Testing to

DVI/HDMI standards receiver products over a wide

range of operating conditions can now be automated

using simple, graphical controls and a set of industry-

standard adapter accessories.

References

1. HDMI Specifications Version 1.0

2. Compliance Test Specifications (CTS) Version 1.0a

3. Physical Layer Compliance Testing for HDMI

Using TDSHT3 HDMI Compliance Test Software

(Tektronix Application Note 61W-17974-1)

Figure 10.

HDMI eye diagram captured with TDSHT3 application software.