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AD679SJ Datasheet(PDF) 9 Page - Analog Devices |
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AD679SJ Datasheet(HTML) 9 Page - Analog Devices |
9 / 12 page AD679 REV. C –9– INPUT CONNECTIONS AND CALIBRATION The high (10 M Ω) input impedance of the AD679 eases the task of interfacing to high source impedances or multiplexer channel-to-channel mismatches of up to 300 Ω. The 10 V p-p full-scale input range accepts the majority of signal voltages without the need for voltage divider networks which could dete- riorate the accuracy of the ADC. The AD679 is factory trimmed to minimize offset, gain and lin- earity errors. In unipolar mode, the only external component that is required is a 50 Ω ±1% resistor. Two resistors are re- quired in bipolar mode. If offset and gain are not critical (as in some ac applications), even these components can be eliminated. In some applications, offset and gain errors need to be trimmed out completely. The following sections describe the correct pro- cedure for these various situations. BIPOLAR RANGE INPUTS The connections for the bipolar mode are shown in Figure 5. In this mode, data output coding will be twos complement binary. This circuit will allow approximately ±25 mV of offset trim range ( ±40 LSB) and ±0.5% of gain trim range (±80 LSB). Either or both of the trim pots can be replaced with 50 Ω ±1% fixed resistors if the AD679 accuracy limits are sufficient for ap- plication. If the pins are shorted together, the additional offset and gain errors will be approximately 80 LSB. To trim bipolar zero to its nominal value, apply a signal 1/2 LSB below midrange (–0.305 mV for a ±5 V range) and adjust R1 until the major carry transition is located (11 1111 1111 1111 to 00 0000 0000 0000). To trim the gain, apply a signal 1 1/2 LSB below full scale (+4.9991 V for a ±5 V range) and adjust R2 to give the last positive transition (01 1111 1111 1110 to 01 1111 1111 1111). These trims are interactive so several iterations may be necessary for convergence. A single pass calibration can be done by substituting a bipolar offset trim (error at minus full scale) for the bipolar zero trim (error at midscale), using the same circuit. First, apply a signal 1/2 LSB above minus full scale (–4.9997 V for a ±5 V range) and adjust R1 until the minus full-scale transition is located (10 0000 0000 0000 to 10 000 000 0001). Then perform the gain error trim as outlined above. Figure 5. Bipolar Input Connections with Gain and Offset Trims UNIPOLAR RANGE INPUTS Offset and gain errors can be trimmed out by using the configu- ration shown in Figure 6. This circuit allows approximately ±25 mV of offset trim range (±40 LSB) and ±0.5% of gain trim range ( ±80 LSB). The nominal offset is 1/2 LSB so that the analog range that cor- responds to each code will be centered in the middle of that code (halfway between the transitions to the codes above and below it). Thus the first transition (from 00 0000 0000 0000 to 00 0000 0000 0001) should nominally occur for an input level of +1/2 LSB (0.305 mV above ground for a 10 V range). To trim unipolar zero to this nominal value, apply a 0.305 mV sig- nal to AIN and adjust R1 until the first transition is located. The gain trim is done by adjusting R2. If the nominal value is required, apply a signal 1 1/2 LSB below full scale (9.9997 V for a 10 V range) and adjust R2 until the last transition is located (11 1111 1111 1110 to 11 1111 1111 1111). If offset adjustment is not required, BIPOFF should be con- nected directly to AGND. If gain adjustment is not required, R2 should be replaced with a fixed 50 Ω ±1% metal film resistor. If REFOUT is connected directly to REFIN, the additional gain error will be approximately 1%. Figure 6. Unipolar Input Connections with Gain and Offset Trims REFERENCE DECOUPLING It is recommended that a 10 µF tantalum capacitor be con- nected between REFIN (Pin 9) and ground. This has the effect of improving the S/N+D ratio through filtering possible broad- band noise contributions from the voltage reference. BOARD LAYOUT Designing with high resolution data converters requires careful attention to board layout. Trace impedance is a significant issue. A 1.22 mA current through a 0.5 Ω trace will develop a voltage drop of 0.6 mV, which is 1 LSB at the 14 bit level for a 10 V full-scale span. In addition to ground drops, inductive and ca- pacitive coupling need to be considered, especially when high accuracy analog signals share the same board with digital sig- nals. Finally, power supplies need to be decoupled in order to filter out ac noise. Analog and digital signals should not share a common path. Each signal should have an appropriate analog or digital return routed close to it. Using this approach, signal loops enclose a small area, minimizing the inductive coupling of noise. Wide PC tracks, large gauge wire, and ground planes are highly recom- mended to provide low impedance signal paths. Separate analog |
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