For analog IC design engineers, using matched components in circuits is one of the keys to creating highly accurate circuits. I have worked on many types of power-management chips, and a small, yet very important, part of them would be the matched feedback resistors that contribute to output voltage accuracy.

To optimize the matching of resistors on an IC, you would typically use multiple segments of the exact same size resistors. An advantage to this approach is that process variations, contact resistances, and geometries will stay relatively consistent in every resistor. Therefore, the voltage divider always produces the same ratio.

However, sometimes the designer need only use a fraction of one of these unit resistors. As we all learned back in EE 101, if you need half of a unit resistor, it's easy enough to connect two unit resistors in parallel to produce half the resistance. Consequently, if you need one-third of a unit resistor, three in parallel will work, as the pattern continues.

But what if you need 3/5 or 4/11 of a unit resistor? Admittedly, the more obscure fractions aren't often required, but this technique will work for any particular fraction.

Let's take the example of 3/5 of a unit resistor. The brute-force method of producing 3/5 of a unit resistor is to have a set of five resistors in parallel and put three of those sets in series (Fig. 1). This does work, but it uses 15 unit resistors. To conserve space, you probably want to keep the number of resistors to a minimum, so there's an obvious drawback to this approach.

To simplify the process, divide the resistors into square sets. Starting from the left, circle a set of 3-by-3 resistors and replace it with an equivalent one-unit resistor (Fig. 2a). Repeat the process with the N-by-N resistors that remain until you can do no more (Fig. 2b). The result: What started out as 15 resistors quickly boils down to four.

Figure 3 shows the same method for 4/11 of a unit resistor. Try it with other fractions. It may take a little practice to find the optimum N-by-N resistors to simplify, but it's fairly easy to get the hang of this technique—one that may help save a little time on your next chip.

Reprints

Printer-Friendly

Email this Article

RSS

Submit PlanetEE del.icio.us Digg Reddit Newsvine StumbleUpon Netscape Yahoo MyWeb Live Bookmarks Fark  Submit

Font Size

What's This?

Integrated DSO/DMM Logs 17,000 Data Points 3.5-GHz, Dual-Slant Antenna Meets New WiMax Industry Standard VPX Card Supplies FPGA Computing In A Small, Rugged Form Factor Compact Circuit Breakers Provide Color Illumination Process-Automation Transceiver Saves Board Space Cherry Electrical Products

Synopsys Takes The Analog/Mixed-Signal Plunge October 2, 2008 Electronic Design Update: October 1, 2008 For Checking Software Without Hardware, FPGAs Are The Answer ESL Platform Looks To Solidify Baseband PHY Design Flow September 25, 2008 Electronic Design Update: September 24, 2008 Tools Take On IC-Package And SiP Design Challenges

1) Build A Smart Battery Charger Using A Single-Transistor Circuit (203 views today) 2) Efficient DC-To-AC Inverters Charge Equipment Racks (85 views today) 3) VIDEO: Under The Hood Of The Tesla Roadster (78 views today) 4) Easily Convert Decimal Numbers To Their Binary And BCD Formats (75 views today) 5) Precision DC motor speed controller (69 views today) ALL TOP 20

Reader Comments Very useful! You just saved the world 1000 DEMM's! Anonymous -June 01, 2006   (Article Rating: ) I really like this technique. An elegant approach that was explained very clearly. Anonymous -May 15, 2006   (Article Rating: ) I really liked this article. I thought it showed a useful technique in an easy-to-understand way. Anonymous -May 12, 2006
POST YOUR COMMENTS HERE Name: Email:
Your Comments: Enter the text from the image below Please refresh the page if you have trouble reading this text.