Battery simulator has variable ESR response

This active circuit represents many battery types.

Barry Galvin, Grae LLC, Simi Valley, CA; Edited by Martin Rowe and Fran Granville -- EDN, March 18, 2010

You may lack experience and hardware when designing battery-operated products. The battery life of a product can depend more on the ESR (equivalent series resistance) than the terminal voltage. This situation is especially true when you use switching regulators to boost the battery voltage. The switching regulator creates a higher load as the battery voltage decreases. The ESR of a real battery is not constant. When you remove a battery load, it reacts and “heals” as its ions rediffuse. Portable electronics may include a low-power or a sleep mode. The device takes short high-power pulses from the battery.

The battery simulator in this Design Idea duplicates a battery’s ESR-response curve. If you place different values in the feedback network, you can obtain various ESR curves. The circuit simulates most battery types, including lithium ion and alkaline. It supplies 0.5 to 4.2V at several amperes to the device under test, and it can simulate the ESR of a variety of battery types. You can change the delay to the final value of ESR by setting the ESR potentiometer. Some battery types exhibit this unique characteristic. It has a large influence on the delivery of pulsed current to a load.

In the circuit, IC₁ supplies a stable voltage, setting the unloaded output voltage (Figure 1). IC₂ provides the necessary inversions for the ESR function. IC₃ and Q₁ form a power-output stage that receives a voltage of 8V. Resistor R₈ limits the power. IC₄ senses the output current through R₉ and provides a gain of 20. This signal goes to the ESR timing circuit, providing both the ESR effect and the response timing.

You can simulate battery chemistries and sizes by varying the component values. If you omit C₄ and replace R_ESR1 through R_ESR4 with one 100-kΩ resistor, only the basic ESR function results. Figure 1 omits power and bypass capacitors.

Applying a 1A load pulse without the capacitor in the feedback network causes the simulator response to closely follow the response of a 2000-mAhr lithium-ion 18650 battery (Figure 2). You can also add the capacitor to the feedback network to make the simulator better represent the response of a small, 200-mAhr lithium-ion battery (Figure 3). With proper adjustment of the circuit, you can produce many response curves. You can download National Instruments’ LabView software and the voltage-ESR curves of selected battery types from Grae LLC.

Talkback

» Submit Feedback

• Why have you removed the PDF format downloadable files ?

  
  Steaphany Waelder - 2010-9-10 08:20:53 PDT

• HI
  
  Why Pdf files of design idea is not accessible anymore?
  
  Yuval

  
  Yuval I - 2010-25-6 02:36:49 PDT

• 
  

  
  

  Can you tell me where specifically I can find the "voltage-ESR curves of selected battery types" that can be downloaded from Grae LLC, as referenced in the article?

  
  

  
  

  
  Thomas VanHeuklon - 2010-6-4 13:52:00 PDT
» Submit Feedback

• Resource Center
• Browse Categories
• Browse Companies

Featured Company

• Rohde & Schwarz

  

  Rohde & Schwarz is an independent group of companies specializing in electronics. It is a leading supplier of solutions in the fields of test and measurement, broadcasting, radiomonitoring and radiolocation, as well as secure communications... more

• Agilent Technologies

  Agilent Technologies Inc. (NYSE: A) is the world's premier measurement company and a technology leader in communications, electronics, life sciences and chemical analysis... more

---

Most Recent Resources

• Atmel's QTouch Library 2.0
• The Impact of Digital Oscilloscope Blind Time on Your Measurements
• LTE-Advanced Technology Introduction
• FREE Webcast: Demystifying TD-LTE: A separation from LTE FDD
• Near Field Communication (NFC) Technology and Measurements