This circuit provides precision, bipolar data conversion using the AD5547/AD5557 current output DAC with the ADR01 precision reference and AD8512 operational amplifier (op amp). This circuit provides accurate, low noise, high speed output voltage capability and is well suited for process control, automatic test equipment, and digital calibration applications.
Figure 1. 4-Quadrant Multiplying Mode, VOUT = –VREF to +VREF (Simplified Schematic)
The AD5547/AD5557 are dual-channel, precision 16-/14-bit, multiplying, low power, current output, parallel input digital-to-analog converters. They operate from a single 2.7 V to 5.5 V supply with ±15 V multiplying references for 4-quadrant outputs. Built-in 4-quadrant resistors facilitate the resistance matching and temperature tracking that minimize the number of components needed for multiquadrant applications.
This circuit uses the ADR01, which is a highly accuracy, high stability, 10 V precision voltage reference. As voltage reference temperature coefficient and long-term drift are primary considerations for applications requiring high precision conversion, this device is an ideal candidate.
An op amp is used in the current-to-voltage (I-V) stage of this circuit. An op amp’s bias current and offset voltage are both important selection criteria for use with precision current output DACs. Therefore, this circuit employs the AD8512 op amp, which has ultralow offset voltage (80 μV typical for B-grade device) and bias current (25 pA typical). C9 is a compensation capacitor. The value of C9 for this application is 2.2 pF, which is optimized to compensate for the external output capacitance of the DAC.
The input offset voltage of the op amp is multiplied by the variable noise gain (due to the code-dependent output resistance of the DAC) of the circuit. A change in this noise gain between two adjacent digital codes produces a step change in the output voltage due to the amplifier’s input offset voltage. This output voltage change is superimposed on the desired change in output between the two codes and gives rise to a differential linearity error, which, if large enough, could cause the DAC to be nonmonotonic. In general, the input offset voltage should be a fraction of an LSB to ensure monotonic behavior when stepping through codes. For the ADR01 and the AD5547, the LSB size is
The input bias current of an op amp also generates an offset at the voltage output as a result of the bias current flowing through the feedback resistor, RFB. In the case of the AD8512, the input bias current is only 25 pA typical, which flowing through the RFB resistor (10 kΩ typical) produces an error of only 0.25 μV.
The AD5547/AD5557 DAC architecture uses a current-steering R-2R ladder design that requires an external reference and op-amp to convert to an output voltage. VOUT can be calculated for the AD5547 using the equation
where D = 0 to 65535 for 16-bit DAC (D is the decimal equivalent of the input code). VOUT can be calculated for the AD5557 using the equation
where D = 0 to 16383 for 14-bit DAC (D is the decimal equivalent of the input code).
The AD8605 is another excellent op amp candidate for the I-V conversion circuit. It also has a low offset voltage and low bias current. The ADR02 and ADR03 are other low noise references available from the same reference family as the ADR01. Other low noise references that would be suitable are the ADR441 and ADR445 products. The size of the reference input voltage is restricted by the rail-to-rail voltage of the op amp selected.
These circuits can also be used as a variable gain element by utilizing the multiplying bandwidth nature of the R-2R structure of the AD5547/AD5557 DAC. In this configuration, remove the external precision reference and apply the signal to be multiplied to the reference input pins of the DAC.