Happy Birthday SAELIG! 29 years old!

On April 28th 1988, I registered the name "The Saelig Company" as a DBA to start a small part-time business while I was still employed as an electronics design engineer at a large multinational company in Rochester NY. ('saelig' means 'happy, prosperous, and blessed' and is a word still used in German to signify divine blessing.) 

I had seen the intermittent layoffs and decided the only way to progress was to start my own thing.  This was in the days before the internet of course:  technical product information was distributed by means of free magazines and 'bingo cards'.  I saw many overseas companies offering their wares but with overseas addresses for inquiry.  I contacted more than 100 of them to see if they needed an engineer in America who could handle technical inquiries and sales for them.  One company did - Triangle Digital Services of London, who made a unique Forth-based controller board. So I employed the services of an answering service for phone calls, and MailBoxes Etc. for their fax number for purchase orders as they came in.  More companies then started to use us, based on that initial success.

In 1998 the multinational company offered a buyout , which I took in order to run things full-time.
 
We soon outgrew a small bedroom and moved house in 2001 to use its large basement.  We soon outgrew that too and moved the business to an office park in Bushnells Basin in Rochester NY.  After enlarging those offices several times, and growing in staff numbers, we moved to our present location in Fairport in 2012 so we could double the size of our warehouse and offices.

Thank you to all our many customers - who range from individuals to The White House, from universities to the military and Fortune 500 companies - for your continued trust in us as your technical suppliers!

Saelig specializes in creating markets for unique measurement and control products, coupled with high quality technical support.  We ship to customers throughout North America and the world. 
As a technical office for overseas and domestic companies, we are eager to promote new and unique products to our large customer base. Our engineers and marketing & sales staff assist with USA inquiries and sales, providing quotation, credit-checking, importing, and shipping assistance – in effect, creating an instant USA office. 

Saelig is a new breed of distributor, with a growing reputation for finding and sourcing unique products;  we are a full-service establishment, offering marketing promotion, technical advice, sales fulfillment, and comprehensive after-sales support.   We talk with our customers, responding promptly to every request, complaint or compliment.   We offer free tech support via phone and email.  Our customers know they can reach us and get help.  We have grown a sophisticated online presence that encompasses effective on-line sales shop, Google Adwords and FaceBook advertising, contact with editors and product reviewers, using regular newsletters to target a wide range of end-users, including: automation, agriculture, automotive, aerospace & defense, medical & pharmaceutical manufacturing, etc. Products lines are offered at highly competitive prices, accompanied by full in-house technical support, exceptional customer service, and fast delivery. 

Our Key Market Segments consist of:  (i) Electronics Manufacturers (e.g. Intel, Microsoft, Texas Instruments, ON Semiconductor, Sony, Honeywell, GM, Ford, Boeing, Northrup-Grumman, Lockheed-Martin, Fortune500 companies, etc. (ii) Defense Contractors. 24 of the 30 biggest defense contractors are our customers.  (iii) DOD and Government.  The Army, Navy, Air Force, Coast Guard, NASA, NSA, DHS, FBI, CIA, The White House and many other State and Federal agencies are our customers. Our GSA Schedule GS-07F-281AA makes these sales easier.  (iv) Education (MIT, Harvard, Yale, Cornell, NYU, Columbia, Notre Dame, USC, UCLA, Stanford, and many other colleges, as well as educational supply houses)  (v) Individual End-users   - often from recommendation by friends and colleagues.

Typical Marketing Efforts:

1)      We issue press releases (at no charge to our suppliers) to over 300 editors, magazines, and blogs who readily receive our submissions since they know that we bring interesting products to their readers. 

2)      We use Facebook, YouTube, Google+, LinkedIn, Pinterest, Twitter and other social media channels to link, cross-promote, integrate, advertise, and most of all to connect with existing and potential customers. We create technical videos in our own full-equipped studio (at no cost to our suppliers).

3)      We use Adwords, adCenter and other PPC channels, and track our traffic and revenue results with Google Analytics.

4)      We personally contact editors and product reviewers with samples provided by the manufacturer (if appropriate).

5)      We use our monthly email newsletter to target a wide range of end-users, including: automation, automotive, aerospace & defense, computers, controls, embedded systems, medical & pharmaceutical manufacturing, motion control, R&D, wireless, consumers, etc.  Our huge customer list includes many government, military, education, and Fortune 500 clients.

6)      More than 800 online sources link to our website – many of them from press releases and articles we have written.  (Google “Saelig” and see the many links to our web pages and social media channels on the first few pages of results.)

We have extensive experience in importing and exporting goods and can facilitate shipping, duties, customer credit checking, etc. and, in general, act as an instant sales office for our clients.

Here's to another 29 years!

Automotive Keyless Entry Testing

Keyless entry

You will require a PicoScope to perform this test. A list of suitable accessories can be found at the bottom of this page.

The purpose of this test is to evaluate the operation of keyless entry and keyless starting systems with Pico Technology’s Keyless entry signal carrier detector. There are many different names for the same system, but it is most commonly referred to as smart entry/start or Passive Keyless Entry (PKE).
Safety notice – please be advised that these systems utilize radio waves. If you have a pacemaker, these radio waves may influence the operation of the pacemaker.
Please note that once the vehicle has been locked, the system constantly searches for a key within the detection zones. For initial testing, you will have to lock the vehicle and place the key outside of the zones. This will make the Keyless entry signal carrier detector able to pick up a signal.
Note: Bodywork repairs with any additional paintwork to the door handles can have a considerable effect on the operation of the keyless entry system.

How to perform the test

Accessories TA330 Keyless entry signal carrier detector PicoScope settings: Channel A Keyless entry  Detector DC coupled Input range: ± 5 V Time base 1 s/div Sample count 1 MS Trigger – no trigger required at first but may be useful later on when you are getting clearer capture Channel A: Auto rising edge Time base 1 ms/div Approximately 2 V ​

How to connect PicoScope

Make sure that the vehicle is locked and that the key is outside the detection zones.
Connect the Keyless entry detector to Channel A on the PicoScope
Run your scope by pressing either the spacebar on your keyboard or the Go button in PicoScope
Hold the Keyless entry detector up to the door handle. Start around 300 mm away from the door handle and move it closer or further away until you find the signal.
Stop the scope by pressing either the spacebar on your keyboard or the Stop button in PicoScope.
Use the Waveform Buffer to scroll through your captured waveforms to assess the keyless entry system when the key is out of reach for the vehicle.
All values included in the example waveforms are typical and not specific to all vehicle types.
Channel A. Indicates the low-frequency pulse emitted by a functioning electrical key antenna with the vehicle locked and the key outside of the detection zones.
Refer to vehicle technical data for specific test conditions and results.

Figure 2: Example waveform 1 – ± 5 V and 1 s/div

1. Low-frequency signal emitted by a functioning electrical key antenna at an approximate interval of 0.25 seconds.
2. Note how the voltage changes across the capture. This is due to the Keyless entry detector being moved closer to the door handle. The closer it gets the stronger the signal.

Figure 3: Example waveform 2 – ± 5 V and 1 ms/div

Changing the base time to 1 ms/div and adding a trigger to Channel A on auto rising edge of approximately 2 V has made it easier to see a clearer waveform.

Figure 4: Example waveform 3

Diagnosis

The output from a functioning electrical key antenna can be measured using the keyless entry detector, confirming activity of the antenna under test. Locking the vehicle and removing the key will trigger the LF signal to start searching for a key in the detection zone as in example waveform 1. Each antenna transmits the request signal received from the certification ECU and forms a key detection area to detect the presence of a key. The detection area formed by the front door antenna and outside luggage antenna is approximately 0.7 to 1.0 m (2.30 to 3.28 ft.) from the outside handle of the front door and rear bumper.
When the key is brought into the detection area the signal from the electrical key antenna will change. This is visible in Example waveform 3. The voltage no longer spikes (depending on where the key detector is placed).

Figure 5: Example waveform 4 – ± 5 V and 1 s/div with key in detection zone

It is worth noting that most systems will extend the pulse time if the vehicle’s sensor cannot find a key in the detection zone or if the touchpad on the handle is pressed in a specified time. This usually happens after a period of 5 days, changing the signal from 25 ms to 75 ms. If the vehicle is left longer (approximately 14 days), with no activation or key detected, the system will deactivate to avoid draining the battery.

Figure 6: Detection zones

Further uses

The keyless entry signal carrier detector can also be used to detect start systems. Most vehicles equipped with a smart entry will also have a keyless start system. Electrical key oscillators are positioned at various points throughout the vehicle to help detect when the key is in the car.
Electrical key oscillators can be pinpointed with the keyless entry detector lead by “sniffing” out the emitted radio waves. As with the electrical key antennae, the closer you are to the source, the greater the output. This process can also be used to check if the start/stop button is working correctly.

Figure 7: Example waveform 4

It is also important to note that the system times out at around 30 secs of the door being opened. It can only be started again when the door has been closed or opened, or by operating the courtesy light switch.

Troubleshooter

1. Key battery – if you have any entry issues with a vehicle, your first port of call should always be to check the battery in the key fob.
2. Vehicle battery – It is also recommended to check the status of the battery before you move on testing the entry system.
3. Bodywork - Any additional paintwork to the door or the door handle could affect the output of the electrical door antennas.
4. Location - Any facilities that generate strong radio waves, such as a TV tower, power plant, broadcast station or gas station will have an impact on the signals.
5. Mobile phones – Carrying a mobile phone near or with the key may also affect the entry system
6. The system is turned off – Some manufacturers give the customer the option to turn the keyless entry/start system off.
7. Programming – It may be that the key isn’t programmed to the vehicle.

While the Keyless entry detector can provide a non-intrusive indication of electrical key antenna’s and electrical key oscillators’ activity, there may be additional diagnosis methods at your disposal. Most manufacturers will utilize self-diagnosis procedures or allow for controller interrogation with a scan tool which can support any errors found with keyless entry and keyless start.
For vehicles without self-diagnosis facilities, or where the relevant scan tool/software cannot gain controller access, the Keyless entry detector provides essential information on whether the system is operating as it should or if there are certain dead zones where a key oscillator is no longer working and the key cannot be detected.

Disclaimer
This help topic is subject to changes without notification. The information within is carefully checked and considered to be correct. This information is an example of our investigations and findings and is not a definitive procedure. Pico Technology accepts no responsibility for inaccuracies. Each vehicle may be different and require unique test settings.

Should I call that meeting? This says it all!

Simulate, Stimulate, Test… RFID Solution Note

Background

Radio Frequency Identification (RFID) is an automatic method of collecting data from tags and transmitting it directly into computer systems using radio waves and without human intervention.

An RFID tag is an object that can be integrated into or attached to a product, animal, or person for the purpose of identification and tracking. The tags are read by an RFID reader using radio waves.

Most RFID tags contain at least two components. One is an integrated circuit for storing and processing information, modulating and demodulating a radio-frequency (RF) signal, and other specialized functions. The second is an antenna for receiving and transmitting the signal.

RFID tags are powered in a variety of ways:

·         Passive. Passive tags are pure passive devices that are powered by the incoming radio signal, and require no internal power source. Most passive tags signal by backscattering the carrier wave and modulating it to transmit data.

·         Active and semi-passive (also known as battery-assisted or semi-active). Active and semi-passive tags require a power source, usually a small battery.

·         Beacon. Beacon tags also require a power source. They transmit autonomously in a blink pattern and do not respond to interrogation.

Communications from active tags to readers are typically much more reliable (generating fewer errors) than those from passive tags and are much more robust in complex RF environments since they can transmit at much higher power levels.

Requirement

An excellent application of RFID technology is in the field of contactless RFID smart cards, which are used for electronic payment in Metro systems. These money cards employ a passive RFID tag using Manchester coding at 212 kbps in the 13.56 MHz range. A proximity of 10 centimeters or less is required for communication.

In order to test RFID readers, signals need to be generated by and transmitted to the tag, whose response is received and interpreted by the RFID reader. An arbitrary waveform generator serves as an ideal signal source, simulating the signals transmitted by the RFID reader.

In order to test the RFID reader, the waveform generator must be able to generate a 13.56MHz carrier wave together with a series of binary (0/1) codes that can be combined in any sequence. The waveform is output for at least 16ms, and the ASK modulation index must have a range of at least 5%-40%. An example of the waveform is shown in below:

Solution

Tabor Electronics’ Wonder Wave family of Arbitrary Waveform Generators (AWGs) offers an outstanding solution for the testing of RFID readers and tags.

Wonder Wave is easily programmed to generate the carrier wave and the data specified in the above example. First, the carrier wave and the data are stored in memory. A sequence is then programmed with the required data. Background noise and frequency variations can then be applied to test the reliability of the unit.

Wonder Wave’s powerful sequence generator provides outstanding support for highly complex applications, offering storage of 10,000 repeatable waveform segments, with up to 4 million memory points.

Wonder Wave is supplied with ArbConnection – Tabor’s comprehensive software tool that controls AWG operation, and supports the creation of unique, arbitrary waveforms using its powerful Waveform Composer.

For More Information

To learn more about Tabor’s solutions or to schedule a demo, please contact Saelig Company, Inc.

Released today! Siglent's new 200MHz 2-ch scope is only $379!!!

http://www.saelig.com/siglent-sdsx-series/sds1202x-e.htm

Saelig Intros Economical 200MHz SDS1202X-E “Super Phosphor” Oscilloscope 

              Fast refresh rate, advanced triggering, deep memory help this new scope break a new price/performance barrier

Saelig Company, Inc. (www.saelig.com) has introduced the Siglent SDS1202X-E 200MHz Digital Oscilloscope with improved Super Phosphor Technology at a remarkably affordable price. With a real-time sampling rate of 1GSa/s, this new 200MHz scope features waveform capture rates of up to 100,000wfms/s in normal mode and 400,000wfms/s in sequence mode.  The SDS1202X-E has a waveform record memory of up to 14Mpoints, and a 256-level color and intensity grading and color temperature display. Together, these technologies have been collectively dubbed by the manufacturer as “SPO” (Super Phosphor Oscilloscope) technology. The low-noise design allows measurements of very small signals, and the scope supports 500uV/div to 10V/div voltage settings, with most of the common adjustments quickly accessible with single-button front-panel control.

The SDS1202X-E Oscilloscope’s design includes a hardware co-processor that delivers measurements quickly and accurately, facilitating an array of advanced measurement and math capabilities (FFT, integral, differential, square root) with serial decoding (I2C, SPI, UART, RS232, CAN, LIN) included as standard.  The 1 million-point FFT math function gives the SDS1000X-E improved high frequency resolution when observing signal spectra compared to similar products. The History function can record up to 80,000 frames of waveforms, easily accessible from the control panel. 

The SDS1202X-E Oscilloscope includes an innovative digital trigger system with high sensitivity and low jitter, producing stable waveform displays.  Multiple powerful triggering modes are provided, including serial decode triggering. Thirty-eight automatic measurements and statistical functions are also included to support electronics testing and a high-speed Pass/Fail capability. Also included are a variety of useful interfaces: USB Host, USB Device, LAN (VXI-11, LXI-C), Ext Trig, Pass/Fail, Trig Out, and the capability of accepting SCPI remote control commands.

The SDS1202X-E Oscilloscope is manufactured by Siglent Technologies, which has been providing high quality digital storage oscilloscopes to customers all over the world since 2002, exporting to more than 40 countries. With more than 13 years of experience in DSO research and manufacturing, Siglent is one of the world’s leading DSO manufacturers. 

The features and performance of Siglent’s new SDS1000X-E cannot be matched anywhere else in this price class. It is available now from Saelig Company, Inc.  A full range of current and voltage probes is also available.

High Current, High Power 45MHz Differential/Dual-Channel Signal Amplifier

Model 9260 Amplifier has 45MHz bandwidth, 34Vpk-pk output into 50 ohms with up to 10W output power

The Tabor Model 9260 is a bench-top dual-channel DC-coupled wideband amplifier, designed for high-frequency and high-current signal amplification. With a wide bandwidth of 45MHz, and delivering 34Vpk-pk output into 50 ohms with up to 10W output power, the 9260 is an ideal complimentary amplifier to any signal source that needs a supporting power boost for demanding applications. With a peak output current of 1A, the 9260 enables a continuous power output of up to 10W, making it ideal for a range of pulse applications.

The 9260 can be configured to be used as two single-ended independent signal channels, or as a one input with two differential outputs. The 9260’s amplifier inputs can be configured to match different source impedances such as 50ohms, 75ohms, or 1Mohm. There are two additional inputs for each channel, allowing the summation of two signals or providing an external DC level offset. The three inputs for each channel are: Main Input (front panel - signal in); Auxiliary Input (rear panel - summing input); DC Offset Input (rear panel - offsetting the signal level within the specified output level window).

While the 9260’s standard configuration enables a maximum output voltage of 34Vpk-pk into 50 ohms with a gain of x10, other custom gains, such as x15 can be ordered at the time of purchase, thus offering an even wider variety of choices to suit application needs.

Applications for the 9260 include: piezoelectronics, transducer characterization, MEMS, general electronics and scientific applications, or any wide bandwidth application that requires high voltage and high current amplification.

The Model 9260 is supplied in a sturdy 2U half-19”-rack metal case with prop-up feet that is sized 12.4” x 4” x 15.6” (WxHxD)  and weighing 7.7lbs. Designed and made in Israel by world-leading provider of high-end signal sources Tabor Electronics, the 9260 is available now from Saelig Company Inc. Fairport, NY. info@saelig.com  For detailed specifications, free technical assistance, or additional information, please contact Saelig at 1-888-7SAELIG, via email: info@saelig.com, or visit www.saelig.com

Introducing GW Instek's New MSO-2000E Series!

GW Instek MSO-2000E Series

Models

·         MSO-2072E

·         MSO-2074E

·         MSO-2102EA

·         MSO-2014EA

·         MSO-2202EA

·         MSO-2204EA

The MSO-2000 series are mixed-signal oscilloscopes which offers 2 or 4 analog channels + 16 digital channels. They offer complete analysis and debugging capabilities at an economical price.   The "A" versions (MSO-2000EA) include a dual channel 25MHz arbitrary waveform generator. The series features bandwidth selections of 70MHz, 100MHz, or 200MHz. The real-time sampling rate is 1GSa/s per channel. The 8-inch 800*480 TFT LCD and the minimum 1mV/div vertical range allow the MSO-2000 series to measure even very small signals and clearly display measurement results.

The MSO-2000 series provides  a 10Mpt sample memory to retrieve and analyze waveforms. Users can choose 1k, 10k, 100k, 1M or 10M memory depth. Short memory depth/high sample rate allows users to observe fast-changing waveforms, whereas long memory depth aids debugging variable waveforms. The MSO-2000 series is equipped with waveform search and segmented memory functions to expand the versatile applications of 10Mpt large memory. The segmented memory can be divided the maximum into 29,000 sections for users to bypass any unimportant waveforms so as to swiftly search all required waveforms. With the segmented memory function, more meaningful waveforms can be saved and target waveforms can be displayed rapidly. Users can rapidly search desired waveforms according to the required trigger conditions.

16-channel logic analyzer has a memory depth of 10Mpts per channel, which helps display and analyze longer digital signal patterns with sufficient information for analysis. The minimum input logic swing of the analyzer is ±250 mV - the digital channels are highly sensitive with respect to input.   Standard bus trigger and decoding functions include serial and parallel bus such as I2C, SPI, UART (RS232/422/485) and CAN/LIN bus for automotive communications. The parallel bus function is only for digital channels. Bus waveforms can be triggered and decoded in real time.            

In addition to a 16-channel logic analyzer, MSO-2000EA has a built-in dual channel 25MHz 14-bit arbitrary waveform generator with a modulation capability and a sample rate of 200MSa/s;  5 standard output waveforms (Sine, Square, Pulse, Ramp, DC, Noise) and 7 user-defined waveforms (Sinc, Gaussian, Lorentz, Exponential Rise, Exponential Fall, Haversine, Cardiac); AM/FM/FSK modulation and sweep function. The user friendly interface is the ideal choice for applications such as circuit simulation and education tests.

More details here!

New Smaller TEMcell for Precompliance Testing

When it comes to pre-compliance EMC testing, radiated emission tests are typically carried out in expensive, dedicated anechoic chambers, using antennas to pick up the radiated signals.  Several antennas are needed to cover the complete required frequency range. Anechoic chambers require a large space commitment - and the equipment cost for a standard conformance setup is very large.

Engineers usually rely on past experience and on best practices in order to design products that are EMC-compliant. But maybe more than 50% of products fail their initial testing. When an engineer sends a new product for compliance testing, it is something of a guessing game and failure is very expensive. Not only are re-testing costs high, but project schedules and market introduction is expensively delayed. 

What is needed is an affordable, compact lab set-up to measure radiated emissions on your own premises, prior to compliance testing. A TEM cell is an excellent solution for desktop testing of radiated emissions. Tekbox has developed open TEM cells that cover the complete frequency range up to 2GHz and can even be used at frequencies above that.   Combining a TEM cell with an affordable benchtop spectrum analyzer, products can be tested before and after EMC-related design modifications.  A test set-up using a TEM cell may not deliver exactly the same quantitative results as certified test house measurements. However, it does provide excellent guidance on whether the product design is producing excessive radiated noise.  And engineers can clearly see how changes improve or degrade the EMC performance - or whether it remains unchanged. Using TekBox TEM cells eliminates the guesswork!

A TEM cell is a basically an RF stripline device, designed for evaluating radiated emissions and immunity testing of electronic devices. It is not a replacement for an anechoic chamber, but it is a convenient and compact first-line alternative. 

A TEM cell consists of a septum, the conductive strip in the center section and walls which are connected to ground. The geometry is designed to present as a 50ohm stripline. The device under test (DUT) is placed in between the bottom wall and the septum.

TBTC0 is a new TEM cell with dimensions 15.3" x 4.0" x 1.1".  TEM cell connectors: N-female

The four models TekBox TBTC0/1/2/3 are so called “open TEM cells” with no side walls, which allows for convenient placement of the DUT.  While it may pick up some RF background noise, this, however, can be taken into account by doing a “blank” measurement of the cell output signal before powering on the DUT.

Tekbox open TEM cells have a better frequency response compared to standard TEM cells of similar size. TEM cells normally suffer from higher order wave modes, which limits the usable bandwidth.  But a unique design feature of the Tekbox TEM cells implements resistance perpendicular to the desired propagation direction of the wave. Consequently higher order wave modes and resonances are suppressed.

All TEM cells are supplied with a 50ohm/25W RF termination, a DC block to protect the spectrum analyzer or RF receiver input, and a N-Male to N-Male coaxial cable. 

New scopes from Teledyne LeCroy!

Teledyne LeCroy has announced some new scopes to add to its high-end offerings: the WaveSurfer 510 and HDO4000A series.

The WaveSurfer510 is a 1GHz 4-ch scope with 10GSa/s sampling on all 4 channels. 16Mpts/ch memory, a huge 12.1" touchscreen display and 8-bit vertical resolution.

The HDO4000A series are 200MHz - 1GHz 12-bit 4-channel scopes with 2.5GSa/s sampling, 12.5Mpts/channel memory and that terrific 12.1" touchscreen display.

Details here:  http://www.saelig.com/category/teledyne-lecroy-oscilloscopes.htm

Coming very soon ...

Siglent has just announced a 200MHz scope that breaks a new price/performance barrier!

The SDS1202X-E 200MHz Digital Oscilloscope offers improved Super Phosphor Technology at a remarkably affordable price. With a real-time sampling rate of 1GSa/s, this new 200MHz scope features waveform capture rates of up to 100,000wfms/s in normal mode and 400,000wfms/s in sequence mode.  The SDS1202X-E has a waveform record memory of up to 14Mpoints, and a 256-level color and intensity grading and color temperature display. Together, these technologies have been collectively dubbed by the manufacturer as “SPO” (Super Phosphor Oscilloscope) technology. The low-noise design supports 500uV/div to 10V/div voltage settings, with most of the common adjustments quickly accessible with single-button front-panel control.

The SDS1202X-E Oscilloscope’s design includes a hardware co-processor that delivers measurements quickly and accurately, facilitating an array of advanced measurement and math capabilities (FFT, integral, differential, square root) with serial decoding (I2C, SPI, UART, RS232, CAN, LIN) included as standard.  The 1 million-point FFT math function gives the SDS1000X-E improved high frequency resolution when observing signal spectra compared to similar products. I/O interfaces include USB Host, USB Device, LAN, Pass/Fail, and Trigger Out. The History function can record up to 80,000 frames of waveforms, easily accessible from the control panel.

The SDS1202X-E Oscilloscope includes an innovative digital trigger system with high sensitivity and low jitter, producing stable waveform displays.  Multiple powerful triggering modes are provided, including serial decode triggering. Thirty-eight automatic measurements and statistical functions are also included to support electronics testing and a high-speed Pass/Fail capability. Also included are a variety of useful interfaces: USB Host, USB Device, LAN (VXI-11, LXI-C), Ext Trig, Pass/Fail, Trig Out, and the capability of accepting SCPI remote control commands.

Coming soon!!!

#wednesdaywisdom for EMC engineers

This memory map can be found in the video "Introduction to Electromagnetic Compatibility - Magic, Art, or Good Engineering Practice?" by presenter Tooraj Forughian at https://www.exploregate.com/video.aspx?video_id=198.