CN0052: Unipolar, Precision DC Digital-to-Analog Conversion using the AD5450/AD5451/AD5452/AD5453 8-/10-/12-/14-Bit DACs

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OVERVIEW

Circuit Note PDF, 09/2010 (pdf, 112 kB)
Benefits & Features
  • Programmable output levels
  • Inverting signal configuration
  • High performance, low noise
    Applications: 
  • Electronic Test & Measurement

CIRCUIT FUNCTION AND BENEFITS

The circuit described in this document is a high-performance, unipolar, precision DAC configu­ration which employs the AD5450/AD5451/AD5452/AD5453 family of precision multiplying DACs, the OP177 low-noise, high precision operational amplifier (op-amp) and the ADR01 precision 10 V reference. Because the op amp dictates the overall circuit dc performance in terms of precision, the OP177, a high precision, low noise op amp, is well matched for performance-driven applications. This circuit also uses the ADR01, which is a high accuracy, high stability, 10 V precision voltage reference. Because voltage reference temperature coefficient and long-term drift are primary considerations for applications requiring high precision conversion, this device is also an ideal candidate.

Figure 1. Unipolar Precision DC Configuration (Simplified Schematic: Decoupling and All Connections Not Shown)

CIRCUIT DESCRIPTION

The circuit uses the AD5450/AD5451/AD5452/AD5453 CMOS, current-output DACs, which provide 8-, 10-, 12- and 14-bit operation, respectively. Because this is a current-output DAC, an op amp is required for current-to-voltage (I-V) conversion at the output of the DAC. Because an op amp bias current and offset voltage are both important selection criteria for precision current output DACs, this circuit employs the OP177 op amp, which has ultralow offset voltage (25 μV) and bias current (2 nA). The OP177 and the AD5450/AD5451/ AD5452/AD5453 can be easily configured to provide a two-quadrant multiplying operation or a unipolar output voltage swing, as shown in Figure 1.

The AD5450/AD5451/AD5452/AD5453 are designed on a 5 V CMOS process and operate from a VDD power supply of 2.5 V to 5.5 V. The DACs accept VREF input ranges up to 10 V, as shown with the ADR01 reference in Figure 1. The ADR01 requires a supply voltage (VDD1) of 12 V minimum and can be driven from the same supply voltage that powers the output amplifier.

When an output amplifier is connected in unipolar mode, the output voltage is given by:

VOUT = -VREF (D/2N)

where D is the digital word loaded to the DAC, and N is the number of bits (D = 0 to 255 (8-bit AD5450); D = 0 to 1023 (10-bit AD5451); D = 0 to 4095 (12-bit AD5452); D = 0 to 16,383 (14-bit AD5453).

The input offset voltage of an op amp is multiplied by the variable noise gain (due to the code-dependent output resis-tance 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, may 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.

Relative accuracy or endpoint nonlinearity is one of the most widely used techniques in determining the accuracy perform-ance of a DAC circuit. This is a measure of the maximum deviation from a straight line passing through the endpoints of the DAC transfer function. It is measured after adjusting for zero and full-scale error and is normally expressed in LSBs. Figure 2 shows the performance of the circuit shown in Figure 1 using the AD5453 14-bit DAC and an OP177 amplifier.

Figure 2. AD5453 14-Bit DAC Relative Accuracy Plot

Excellent grounding, layout, and decoupling techniques must be used for proper operation of the circuit. All power supply pins should be decoupled directly at the pin with a low inductance (low ESL) 0.1 μF ceramic capacitor. The connection to ground should be directly to a large area ground plane. Additional decoupling using a 1 μF to 10 μF electrolytic capacitor is recom-mended on each power supply where it enters the PC board. The decoupling capacitors are not shown in Figure 1 for simplicity.

To optimize high frequency performance, the I-V amplifier should be located as close to the DAC as possible. The AD5450/ AD5451/AD5452/AD5453 data sheets show the schematics and layouts used for the evaluation boards.

COMMON VARIATIONS

The OP1177 and AD8065 are other excellent op amp candidates for the I-V conversion circuit. They also provide a low offset voltage and ultralow bias current.

The 10.0 V output ADR01 can be replaced by either the ADR02 or ADR03, which are low-noise references available from the same reference family as the ADR01 and provide 5.0 V and 2.5 V outputs, respectively. The ADR445 and ADR441 ultralow noise references are also suitable substitutes which provide 5.0 V and 2.5 V, respectively. Note that the size of the reference input voltage is restricted by the rail-to-rail voltage of the operational amplifier selected.

SAMPLE PRODUCTS USED IN THIS CIRCUIT

Product Description Available Product Models to Sample
AD5450 8-Bit High Bandwidth Multiplying DACs with Serial Interface AD5450YUJZ-REEL7
AD5451 10-Bit High Bandwidth Multiplying DACs with Serial Interface AD5451YUJZ-REEL7
AD5452 12-Bit High Bandwidth Multiplying DACs with Serial Interface AD5452YRMZ AD5452YUJZ-REEL7
AD5453 14-Bit High Bandwidth Multiplying DACs with Serial Interface AD5453YUJZ-REEL7 AD5453WBCPZ-RL AD5453YRMZ AD5453YRM
ADR01 Ultracompact, Precision 10.0 V Voltage Reference ADR01WARZ-R7 ADR01ARZ ADR01AKSZ-REEL7 ADR01AUJZ-REEL7
OP177 Precision Op Amp

To obtain samples of this part, please contact ADI

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