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LTC6754 Datasheet(PDF) 24 Page - Analog Devices |
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LTC6754 Datasheet(HTML) 24 Page - Analog Devices |
24 / 34 page LTC6563 24 Rev. 0 For more information www.analog.com APPLICATIONS INFORMATION In order to simplify the analysis, an intuitive way to look at the output loading is to examine its equivalent half-circuit as shown in Figure 9. With the half-circuit method, any impedance that is shared between the two halves appears as double its original value (e.g. RCM appears as 2 • RCM below). In Figure 8, the external loading by the ADC and the cable termination network of R1, and R2 has no effect on the CM loading of the LTC6563. The range of output CM volt- age will be as follows: VCMO = IO • (50Ω + 2RCM) (1) For the ADJ setting of 00 where Io is 7mA (see Table 1 and Table 5) here is the computation of min VCMO possible (corresponding to RCM = 2Ω): VCMO (minimum) = 7mA • (50Ω + 2 • 2Ω) = 380mV (2) At the other extreme of VCMO when RCM opens, the output CM voltage will only be limited to the LTC6563 output compliance voltage which is about 1V below VCC (or about 2.3V with VCC = 3.3V). Naturally, if the ADJ setting is changed, the VCMO range will vary accordingly. Table 5 shows the minimum com- puted output CM voltage, output full scale swing, and TIA gain (RT) for various ADJ settings applied to the circuit in Figure 7. For a higher Transimpedance gain (RT) or higher ADC FS swing, higher ADJ output current settings can be chosen. Summary of how ADJ affects the TIA gain and differential output voltage swing is tabulated in Table 5. Here is a sample calculation of the values in Table 5 (50Ω Net diff load, full tilt) for ADJ 00 as an illustration: a. Output current values (ADJ 00) with max input current of 90µA (from Table 2): 12mA, 2mA b. Net diff output load: 50Ω (25Ω on each output) c. RT Calculation: RT(k Ω) = 25 Ω[(12mA – 2mA) – (2mA – 12mA)] 90µA = 5.56kΩ VCC I1 50 2 • RCM 4 TO OPEN OUT TERM LTC6563 6563 F09 Figure 9. CM Half-Circuit Equivalent for a Non-Grounded External Load The internal CM CTRL resistance varies from about 2Ω to essentially an open circuit. At the lower end of the CM CTRL resistance, RCM, the output CM voltage will be at the minimum it can reach. And at the higher end of RCM, it will be at the maximum it can reach. The external CM resistance can also vary greatly, depend- ing on whether any external loads are terminated differ- entially or to GND. Detailed Example 1: Differential Termination ONLY With an external load connected, the output CM current splits between the internal TERM pin and the external load. However, with the configuration shown in Figure 7 and simplified in Figure 8, with no external CM DC current path to ground, the entire output CM current must flow through the internal TERM resistor(s). Table 5. CM Minimum Voltage and Other Operating Performance Values for Various ADJ Settings of Figure 7 ADJ1 ADJ0 CM/AVERAGE OUTPUT CURRENT IO (mA) RT (kΩ) ADC FS DIFF VOLTAGE SWING WITH FULL TILT (mVP-P) MIN CM VOLTAGE (mV) 0 0 7 5.6 500 380 0 1 14 11.1 1000 756 1 0 21 16.7 1500 1134 1 1 28 22.2 2000 1512 |
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