Engineers often need dc voltage sources with very high precision and good resistive and/or capacitive load-driving capability for industrial applications. However, precision benchtop power supplies can be very expensive if high accuracy also is required. IC-based dc voltage sources, such as references and regulators, cost less but only partially satisfy the requirements. References have good dc accuracy yet lack resistive or capacitive load-driving capability. On the other hand, regulators have the load-driving power but not the necessary accuracy and software programmability.

A power output stage that can drive capacitive loads is shown in the figure. It has a precision input circuit and voltage programmability from ­2.5 to +2.5 V, with 16-bit accuracy. The circuit employs a dual auto-zero amplifier, A1a-A1b (AD8552); a high-output current amplifier, A2 (AD8531); a 16-bit serial-input digital-to-analog converter (DAC), A3 (AD5542); and a precision voltage reference, A4 (AD780). If programmability isn't needed, the circuit can use a fixed reference instead of the DAC.

Circuit operation goes as follows: The DAC (A3) is configured for bipolar operation when combined with A1a. Its output can be programmed to ±V_REF, which is set to 2.5 V by the AD780. In combination, the DAC and amplifier produce a negligible error. Worst-case, bipolar output-voltage error, V_OUT-BIP, can be calculated as shown in the Equation Listing, where:

D = code loaded to the DAC
V_REF = reference voltage = +2.5 V
V_GE = gain error = ±5 LSB
ZE = zero-scale error = ±1 LSB
INL = integral linearity = ±1 LSB
V_OS = amplifier offset voltage = 5 µV
RD = resistor matching = ±0.00076%
A = amplifier open-loop gain
   = 1,000,000

For example, when the code loaded to the DAC is 1 LSB (code 1000 0000 0000 0001), the worst-case error will be approximately 350 µV. These small errors can be stored as CAL factors in a calibration table if even higher accuracy is required.

The programmed voltage is fed into the unity-gain composite amplifier composed of A1b and A2. This composite amplifier performs close to the ideal, as the input stage of the AD8552 (A1b) provides a very high common-mode rejection ratio (CMRR), power-supply rejection ratio (PSRR), open-loop gain, and very low offset voltage.

The composite amplifier also has a very high output current and good capacitive and resistive load-driving capability due to the AD8531. Additionally, both the AD8552 and AD8531 have rail-to-rail inputs and outputs. Using the equation below, users can calculate the worst-case error of this composite amplifier:

V_OUT = (V_IN ­ V_{IN_DIFF})
V_IN = V_{OUT_BIP}
V_{IN_DIFF} = V_OS + en + V_OUT/A +V_ICM/CMRR +ΔV_S/PSRR

where:

en = amplifier input noise = 20 nV/√Hz
CMRR = 120 dB
PSRR = 120 dB

When light loads are driven (R_L > 500 Ω), the composite amplifier circuit adds less than 10 µV of error to the programmed signal coming out of the DAC. For larger than ±120-mA output currents, A2 limits the output performance.

The above circuit can function as a precision, programmable reference with sink and source output current, or as a low-dropout regulator with excellent load regulation and efficiency. Proper bypassing of the am-plifiers and additional pins on the DAC and DSP are omitted for clarity.

See associated figure.

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?

LED Design Kit Offers Plethora Of Lighting Technologies Board Interfaces GPIB To Modbus JIC Enclosure Family Receives CE Certifications GMR Current Sensor Sports Wide Range HomePlug SoC Interoperates With TIA-1113/IEEE 1901 Standards RFIC Switch Simplifies GSM/AMR And Short-Range Wireless Designs

Automating Analog IP Process Migration C Tools Accelerate HDV Development On Xilinx FPGAs A New Design Inflection Point Forecasting Industry Growth For 2009 And Beyond EDA Retools To Exploit Multicore Architectures Design And Verification Move Up In Abstraction EDA Retools To Exploit Multicore Architectures A New Design Inflection Point

1) Transportation Guidelines For Lithium Batteries Get Updated (261 views today) 2) Build A Smart Battery Charger Using A Single-Transistor Circuit (236 views today) 3) The Field Of Energy Harvesting Begins To Ripen (112 views today) 4) Easily Convert Decimal Numbers To Their Binary And BCD Formats (104 views today) 5) 2008 BEST Electronic Design Winners (100 views today) ALL TOP 20

Reader Comments hello, am doing electronic at school and i need hlpe from u plz plz,i wont to work with u thereplz am in ghana ,and also my dad is ded ,am in west africa ,and am in nugua_accra.plz help me. rapheal yeboeh. rapheal yeboah -July 09, 2005 hello, am doing electronic at school and need hlpe ,from u plz plz,i wont to work with u thereplz am in ghana ,and also my dad is ded ,am in west africa ,and am in nugua_accra.plz help me. rapheal yeboeh. rapheal yeboah -July 09, 2005
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.