TDEMI – 645MHz Real-Time Analysis Bandwidth for Full Compliance Testing


The Gauss Instruments TDEMI eXtreme (TDEMI X) is the latest and most advanced level of full digital measurement equipment for emission testing. Based on the patented TDEMI® real-time technology, upgrading its frequency range is easy by using a number of extensions which can be integrated into the instrument step by step. The frequency ranges are 1 GHz, 3 GHz, 6 GHz, 18 GHz, 26.5 GHz or 40 GHz respectively. A large variety of configuration possibilities makes the TDEMI X a perfect solution for any lab working on civil standards applications (e. g. CISPR, EN, FCC Part 15, ANSI C63.2, ANSI C63.4), military standards (e. g. MIL-461G, but also its previous versions and revisions) as well as avionic standards (e. g. DO-160). The frequency range of the TDEMI X starts at 9 kHz in its standard configuration and can be extended down to 10 Hz by the option MIL/DO-UG or even down to DC by the available option OSC-UG. Like all other TDEMI measurement systems, the TDEMI X measurement systems can be remotely controlled and fully automated via Ethernet (TCP/IP) very easily.

  • Frequency Range from DC up to 40 GHz
  • 645 MHz Real-time Analysis Bandwidth
  • Dynamic range of more than 100 dB
  • 64000 times faster than conventional receivers
  • All 6dB RBWs acc. to CISPR, MIL, DO, and ANSI
  • 3dB RBWs in 145 steps
  • Multi-functional and easily upgradeable
  • Full compliance measurements at all frequencies and in all operation modes
  • Ultra-high resolution and accuracy as well as the shortest overall scan times in the market - all at the same time

The TDEMI X uses the highest performing analog-to-digital converters with the best ratio of signal-to-noise power density available on the market, most modern high-speed FPGAs and in-house designed high performance microwave circuits. The highest measurement accuracy and highest measurement speed is achieved over the entire frequency range starting from 10 Hz up to 40 GHz. The TDEMI X measurement system offers in its standard configuration a fully integrated spectrum analyzer and also a real-time spectrum analyzer. An additional option provides a two-channel oscilloscope, extending the frequency range even down to DC. The TDEMI X can be used in a vast range of applications, including for measurements and testing according to telecommunication standards (eg.ETSI) and all this can be done fully gapless in real-time with an absolutely unique instantaneous bandwidth of 645 MHz and an unrivaled measurement speed and dynamic range of about 100 dB (@0dB attenuation and pre-selection off) or even up to more than 170 dB including the automatically stepped attenuator.

TDEMI – 645MHz Real-Time Analysis Bandwidth for Full Compliance Testing


Using the GAUSS INSTRUMENTS TDEMI X with a real-time analysis bandwidth of 645 MHz and fully gapless evaluation and visualising, the final maximisation can be performed at all frequencies simultaneously. The unique feature of the fully gapless real-time spectrogram mode combines all the advantages of the single frequency mode of a traditional receiver with the possibility to carry out the measurement at all frequencies simultaneously. Two detectors are applied simultaneously, thus CISPR-Average and Quasi-peak detectors can be measured simultaneously in real-time and stored and visualized in real-time.

Fully gapless processing and evaluation of all frequencies is given, which is a mandatory requirement of CISPR 16-1-1 Ed. 3. Fulfilling all the requirements of the CISPR 16-1-1 2007 till the current version of CISPR 16-1-1 entirely, thus the real-time spectrogram mode can be used for final maximization either for product standards that reference older CISPR 16-1-1 versions or also the current version of the CISPR 16-1-1 version that contains the inclusion of the “FFT-based measuring instrument”.

By applying the real-time analysis bandwidth of 645 MHz the measurement is carried out first in the frequency range of 30 MHz – 645 MHz using Quasi-peak and CISPR-Average detectors including maximization at all angular positions and heights. After characterization in the range from 30 MHz – 645 MHz the second full maximization is performed in the range 645 MHz – 1 GHz. Both measurements are combined to the final test report.

The final test result contains all the measurements of Quasi-peak and CISPR-Average at all frequencies over all positions as well as the maximum emissions. Now, the overall test time corresponds approximately to the test time of a final maximization carried out at two critical frequencies according to the traditional pre-scan and final maximization procedure which was performed in the past. In Addition the total measurement quality is improved and the measurement uncertainty is reduced performing the measurement in the TDEMI X real-time spectrogram mode.

The advantage of using this method is that all operation modes of a device under test can be easily measured in a very short total test time. Complicated test procedures resulting in increased measurement uncertainty are now a thing of the past. Fast and reliable testing is of crucial importance to address today’s short time-to-market cycles.

It is not necessary anymore to perform pre-scan and final maximisation. In addition, evaluation according to the limit lines as well as report generation is performed by the instrument creating a report in MS Word file format which can be integrated into larger documents. Using full automation software such measurements can be also performed fully automated, and radiation patterns and further evaluations can be included in the test report.


 GAUSS INSTRUMENTS


GAUSS INSTRUMENTS develop and produce high quality instruments made in Germany that utilise cutting edge technology to fulfil the requirements of complex measurement tasks. Their goal is to provide an additional benefit by accelerating test and measurement procedures, continuously increasing performance parameters and providing high quality measurement results to their customers. Founded in 2007, the company is a spin-off from the Institute for High-Frequency Engineering of the Technische Universität München.

The research in the field of time domain measurements of electromagnetic interferences (EMI) started in the year 2000 and in the following years resulted in over 50 publications, transactions and journal articles being published on the topic of time-domain EMI measurements.

GAUSS INSTRUMENTS is the manufacturer of the award winning TDEMI Measurement System that uses ultra-high-speed analogue to digital converters and real-time digital signal processing systems to enable ultra-fast tests and measurements for electromagnetic compliance that fulfil the demand for measurements of today’s complex electronic equipment and applications.

The presentation of the first TDEMI Measurement System (TDEMI 1G) at the EMC Zurich 2007 Conference in Munich, was the beginning of what was to become a highly respected product range which covers a wide range of the demands of modern EMC testing.

Customised signal processing solutions are also offered based on their established hardware and software platforms. Using their expertise about real-time digital technology and microwave technologies they are developing systems that are unique in the field of test and measurement.

For further information, please contact Fuseco, your trusted partner in test equipment solutions.


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Top FAQs

Electrostatic discharge (ESD) is the sudden flow of electricity between two electrically charged objects caused by contact, an electrical short, or dielectric breakdown. A buildup of static electricity can be caused by turbocharging or by electrostatic induction.

Simulates electrostatic discharge events directly to the product, or to a nearby conductive surface.


Test Method

The ESD test requires that discharges be made to all exposed surfaces of the EUT, including connector back shells. Contact discharge is to the conducting surfaces of the product and air gap discharges are to non-conducting surfaces. The test also requires that contact discharges be made to a horizontal reference plane and vertical reference plane at locations 10cm from the front, rear and sides of the EUT. The ESD Simulators/Generators/Guns can be used for ESD Testing.


Typical rise time of the ESD pulse waveform is approximately 0.7 - 1nS with a hold time of 30 - 60 nS. (See image)

 


The test simulates ESD events that occur when the user touches the equipment under test or nearby metallic objects (e.g. filing cabinets). The test levels for both the heavy industrial and light industrial/commercial/residential standards are ±2kV and ±4kV for the contact discharge method and ±2kV, ±4kV, and ±8kV for the air gap discharge method.

A transient event is a short-lived burst of energy in a system caused by a sudden change of state. The source of the transient energy may be an internal event or a nearby event. The energy then couples to other parts of the system, typically appearing as a short burst of oscillation.


In electrical and electronic engineering such electromagnetic pulses (EMP) occur internally as the result of the operation of switching devices. Engineers use voltage regulators and surge protectors to prevent transients in electricity from affecting delicate equipment. External sources include lightning (LEMP), electrostatic discharge (ESD) and nuclear EMP (NEMP).


Within Electromagnetic compatibility testing, transients are deliberately administered to electronic equipment for testing their performance and resilience to transient interference. Many such tests administer the induced fast transient oscillation directly, in the form of a damped sine wave, rather than attempt to reproduce the original source. International standards define the magnitude and methods used to apply them.

Simulates high frequency electrical disturbance on power and signal lines due to the switching of inductive loads on the AC line.


Test Method

The test waveform consists of a 15ms burst of pulses at 300ms intervals. The pulses have a rise time of 5ns and a dwell time of 50ns, with a repetition rate of 5 kHz.


For heavy industrial equipment the test levels are:

  • AC lines; ±2kV
  • DC lines;
  • ±2kV Signal lines on cables that could be longer than 3m; ±1kV
  • Process control lines and measurement lines; ±2kV

Noise is directly injected onto power lines through a capacitor and capacitive coupled onto I/O lines using a coupling trench. DC power ports connected to an AC-DC power adapter are not tested.

Surges, or transients, are brief overvoltage spikes or disturbances on a power waveform that can damage, degrade, or destroy electronic equipment within any home, commercial building, industrial, or manufacturing facility. Transients can reach amplitudes of tens of thousands of volts.

Simulates low frequency, high-energy electrical transients on power lines and long distance I/O lines (such as telephone lines) coupled from nearby lightning strikes.


Test Method

Test is applied to AC and DC power ports. The open circuit signal wave-shape has as 1.2µs rise time and 50µs hold time. Surges are applied in common mode (line-to-ground) and in differential mode (line-to-line). All surges are synchronized to the 0°, 90°, 180° and 270° phase angles of the AC voltage. DC power ports are not tested if they are connected to an AC-DC power adapter, in which case the AC-DC adapter should be submitted for testing.


Test levels for the residential, commercial and light industrial generic standard are 2kV common mode and 1kV differential mode on AC power lines. For DC power lines, the test levels are 0.5kV for both differential and common mode. Although the test is not currently required for the heavy industrial generic standard, it suggests test levels of 4kV common mode and 2kV differential mode.

Simulates brown outs and blackouts on AC power lines.


Test Method

This test is applied to AC power ports rated at less than 16 amps per phase. All voltage shifts are synchronized to the zero crossing of the AC voltage.


Typical test levels for the generic light industrial standard involve a 30 percent dip in the line voltage for 10ms, 60 percent dip for 100ms and dropout for 5000ms. There are currently no requirements for Heavy Industrial equipment.

All linear amplifier systems, when given a sufficiently strong input signal, will reach a point where the system departs from a linear relationship between input and output. At this point the system is said to be going into compression or beginning to saturate. Beyond this point, the linear relationship between input and output is no longer valid and the amplifier is no longer considered to be linear. An internationally recognised figure of merit, used for defining the extent of linearity of an amplifier, is the 1dB compression point. This is the point of –1dB departure from linearity. The output power of an amplifier cannot increase indefinitely and when an increase in input power generates no discernible increase in output power, the amplifier is said to be saturated, and by definition the output is not proportional to the input signal. This point is often referred to as Psat on a datasheet or sometimes P3dB. Generally, saturated power is of importance when considering the pulsed power requirements in something like automotive testing while linear power is of importance when considering the AM (amplitude modulation) waveform used in commercial EMC testing.

Thank you for helping our team select the correct product to facilitate testing to the various required standards. Our lab is now equipped with a range of Teseq, IFI and Milmega products and the entire solution fulfils our testing requirements. We really appreciate your technical advice & support.

Scott Emerson

EMC TEST ENGINEER

The Teseq GTEM is a great testing tool to have. We are now performing all pre-compliance testing in-house and saving lots of money which we were spending earlier with test labs. It has given us significant more testing capability and flexibility. Thank you for your help.

Sue Benton

TECHNICAL DIRECTOR

Aside from receiving information when we need to upgrade or purchase an item of test equipment, what we really need from an equipment partner is advice based on industry experience. Thank you for the many hours spent talking to us and answering our questions. This level of customer care is rare in this industry.

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EMC TEST ENGINEER TEAM LEADER

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