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AD2S80ASD883B Folha de dados(PDF) 11 Page - Analog Devices |
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AD2S80ASD883B Folha de dados(HTML) 11 Page - Analog Devices |
11 / 16 page AD2S80A REV. B –11– for sinusoidal signals in phase or antiphase with the reference (for a square wave the DEMODULATOR OUTPUT voltage will equal the DEMODULATOR INPUT). This provides a signal at the DEMODULATOR OUTPUT which is a dc level proportional to the positional error of the converter. DC Error Scaling = 160 mV/bit (10 bits resolution) = 40 mV/bit (12 bits resolution) = 10 mV/bit (14 bits resolution) = 2.5 mV/bit (16 bits resolution) When the tracking loop is closed, this error is nulled to zero unless the converter input angle is accelerating. Integrator The integrator components (R4, C4, R5, C5) are external to the AD2S80A to allow the user to determine the optimum dynamic characteristics for any given application. The section “COMPO- NENT SELECTION” explains how to select components for a chosen bandwidth. Since the output from the integrator is fed to the VCO INPUT, it is proportional to velocity (rate of change of output angle) and can be scaled by selection of R6, the VCO input resistor. This is explained in the section “VOLTAGE CONTROLLED OSCIL- LATOR (VCO)” below. To prevent the converter from “flickering” (i.e., continually toggling by ±1 bit when the quantized digital angle, φ, is not an exact representation of the input angle, θ) feedback is internally applied from the VCO to the integrator input to ensure that the VCO will only update the counter when the error is greater than or equal to 1 LSB. In order to ensure that this feedback “hys- teresis” is set to 1 LSB the input current to the integrator must be scaled to be 100 nA/bit. Therefore, R4 = DC Error Scaling (mV /bit ) 100 (nA /bit ) Any offset at the input of the integrator will affect the accuracy of the conversion as it will be treated as an error signal and offset the digital output. One LSB of extra error will be added for each 100 nA of input bias current. The method of adjusting out this offset is given in the section “COMPONENT SELECTION.” Voltage Controlled Oscillator (VCO) The VCO is essentially a simple integrator feeding a pair of dc level comparators. Whenever the integrator output reaches one of the comparator threshold voltages, a fixed charge is injected into the integrator input to balance the input current. At the same time the counter is clocking either up or down, dependent on the polarity of the input current. In this way the counter is clocked at a rate proportional to the magnitude of the input current of the VCO. During the reset period the input continues to be integrated, the reset period is constant at 400 ns. The VCO rate is fixed for a given input current by the VCO scaling factor: = 7.9 kHz/ µA The tracking rate in rps per µA of VCO input current can be found by dividing the VCO scaling factor by the number of LSB changes per rev (i.e., 4096 for 12-bit resolution). The input resistor R6 determines the scaling between the con- verter velocity signal voltage at the INTEGRATOR OUTPUT pin and the VCO input current. Thus to achieve a 5 V output at 100 rps (6000 rpm) and 12-bit resolution the VCO input cur- rent must be: (100 × 4096)/(7900) = 51.8 µA Thus, R6 would be set to: 5/(51.8 × 10–6) = 96 kΩ The velocity offset voltage depends on the VCO input resistor, R6, and the VCO bias current and is given by Velocity Offset Voltage = R6 × (VCO bias current) The temperature coefficient of this offset is given by Velocity Offset Tempco = R6 × (VCO bias current tempco) where the VCO bias current tempco is typically –1.22 nA/ °C. The maximum recommended rate for the VCO is 1.1 MHz which sets the maximum possible tracking rate. Since the minimum voltage swing available at the integrator output is ±8 V, this implies that the minimum value for R6 is 57 k Ω. As Max Current A MinValue R k = × × = = × =Ω 11 10 79 10 139 6 8 139 10 57 6 3 6 . . – µ Transfer Function By selecting components using the method outlined in the sec- tion “Component Selection,” the converter will have a critically damped time response and maximum phase margin. The Closed-Loop Transfer Function is given by: θ OUT θ IN = 14 (1 + s N ) (sN +2.4)(s N 2 + 3.4 s N +5.8) where, sN, the normalized frequency variable is: sN = 2 π s f BW and fBW is the closed-loop 3 dB bandwidth (selected by the choice of external components). The acceleration KA, is given approximately by K A = 6 × ( f BW ) 2 sec –2 The normalized gain and phase diagrams are given in Figures 4 and 5. |
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