Showing posts with label downprogrammer. Show all posts
Showing posts with label downprogrammer. Show all posts

Friday, September 6, 2013

How fundamental features of power supplies impact your test throughput – Part 1

When it comes to manufacturing of electronic products, reducing test time to improve throughput is virtually always a top priority, because “time is money” as the old saying goes! Usually most all of the attention may be placed on reducing the test time of the banner aspects of the product, such as the RF performance of a wireless device, for example. However, the choice of the DC system power supply can also have a huge impact on your test time and throughput during manufacturing. You may find the lowest cost, more basic-performance DC power supply that meets your immediate needs end up costing you the difference in price many, many times over of that of a higher-performance DC power supply having better throughput performance in the long run!

The DC power supply can incorporate a number of advanced features, such as elaborate triggering and sequencing systems, which will allow you restructure your testing to optimize throughput. However, even fundamental throughput-related features of the power supply can also have a large impact on your test time, including:
  • Command processing time
  • Output up-programming time
  • Output down-programming time
  • Measurement time

Figure 1 illustrates what the command processing and up-programming times are for a DC power supply. The command processing time is the time from when the command is first received to the point where the power supply starts acting on it. In this case it is when power supply’s output starts to change. The up-programming response time is the time the power supply takes for the output to rise and settle within a small band around the final output level, after processing the command instructing it to change its output level.



Figure 1: Power supply command processing and up-programming response times

The down-programming response time is like the up-programming response time except that the power supply is instead being programmed to a lower level. However, you need to look at down-programming independently as short up-programming time does not necessarily guarantee comparably short down-programming time. More basic performance DC power supplies usually lack an active down-programmer circuit that quickly brings down the output. In this case the down-programming response time can be very dependent on how much load the DUT presents to the power supply’s output.

How much difference is there in performance between more basic performance and higher performance DC power supplies on these throughput-related features? It can be considerable; over several orders of magnitude difference. As one example, command processing time can range from up to 100’s of milliseconds for entry-level power supplies to under 1 millisecond for high performance power supplies.
Another fundamental throughput-related feature of a DC power supply is its measurement time. There are a couple of aspects to consider here as well, which I will elaborate on in part 2 of this series on how fundamental features of power supplies impact your test throughput, in an upcoming posting here on “Watt’s Up?” along with tying it all together to show how they affect actual test throughput!

Tuesday, March 27, 2012

If you need fast rise and fall times for your DUT power, use a power supply with a downprogrammer

If you have to provide DC power to a device under test (DUT) and you want the voltage fall time to be just as fast as the rise time, use a power supply with a downprogrammer. A downprogrammer is a circuit built into the output of a power supply that actively pulls the output voltage down when the power supply is moving from a higher setting to a lower setting. Power supplies are good at forcing their output voltage up since that is what their internal circuitry is designed to do. This design results in fast rise times. However, when the supply’s output is changed to move down in voltage, the power supply’s output capacitor (and any additional external DUT capacitance) will need to be discharged. Without a downprogrammer, if there is a light load or no load on the output of the power supply, there is nowhere for the current from the output cap to flow to discharge it. This scenario causes the voltage to take a long time to come down resulting in slow fall times. And this behavior leads to longer test times since you will have to wait for the output voltage to settle to the lower value before you can proceed with your test.

The figures below show an example of the output voltage rise and fall times of a power supply without a downprogrammer under light load conditions. You can see the short rise time (tens of milliseconds) and longer fall time (several seconds).



One of my colleagues, Bob Zollo, wrote an article on this topic that appeared in Electronic Design on February 7, 2012. Here is a link to the article:

https://electronicdesign.com/article/test-and-measurement/If-Your-Power-Supply-Needs-Fast-Rise-And-Fall-Times-Try-A-Down-Programmer-64725

A power supply without an active downprogrammer can have fall times that are tens to hundreds of times longer than a power supply with a downprogrammer. If your test requires you to have fast fall times for your DUT power, or your test requires you to frequently change the voltage on your DUT (both up and down) and throughput is an issue for you, make sure the power supply you choose has a downprogrammer – you won’t have to wait as long for the voltage to move from a higher value to a lower value.