Datasheet ADVFC32 (Analog Devices) - 5
| Fabricante | Analog Devices |
| Descripción | Low Cost Monolithic Voltage-to-Frequency (V/F) Converter |
| Páginas / Página | 7 / 5 — ADVFC32. F/V CONVERSION. BIPOLAR V/F. UNIPOLAR V/F, NEGATIVE INPUT … |
| Revisión | B |
| Formato / tamaño de archivo | PDF / 379 Kb |
| Idioma del documento | Inglés |
ADVFC32. F/V CONVERSION. BIPOLAR V/F. UNIPOLAR V/F, NEGATIVE INPUT VOLTAGE. DECOUPLING. COMPONENT TEMPERATURE COEFFICIENTS
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ADVFC32
Input resistance RIN is composed of a fixed resistor (R1) and a
F/V CONVERSION
variable resistor (R3) to allow for initial gain error compensation. Although the mathematics of F/V conversion can be very com- To cover all possible situations, R3 should be 20% of RIN, and plex, the basic principle is easy to understand. Figure 4 shows R1 should be 90% of RIN. This allows a ± 10% gain adjustment the connection diagram for F/V conversion with TTL input to compensate for the ADVFC32 full-scale error and the toler- logic levels. Each time the input signal crosses the comparator ance of C1. threshold going negative, the one shot is activated and switches If more accurate initial offset is required, the circuit of R4 and 1 mA into the integrator input for a measured time period R5 can be added. R5 can have a value between 10 kΩ and (determined by C1). As the frequency increases, the amount of 100 kΩ, and R4 should be approximately 10 MΩ. The amount charge injected into the integration capacitor increases propor- of current required to trim zero offset will be relatively small, so tionately. The voltage across the integration capacitor is stabilized the temperature coefficients of these resistors are not critical. If when the leakage current through R1 and R3 equals the average large offsets are added using this circuit, temperature drift of current being switched into the integrator. The net result of both of these resistors is much more important. these two effects is an average output voltage which is propor- tional to the input frequency. Optimum performance can be
BIPOLAR V/F
obtained by selecting components using the same guidelines and By adding another resistor from Pin 1 (Pin 2 of TO-100 can) to equations listed in the V/F conversion section. a stable positive voltage, the ADVFC32 can be operated with a bipolar input voltage. For example, an 80 kΩ resistor to 10 V causes an additional current of 0.125 mA to flow into the inte- grator so that the net current flow to the integrator is positive even for negative input voltages. At negative full-scale input voltage, 0.125 mA will flow into the integrator from VIN cancel- ling out the 0.125 mA from the offset resistor, resulting in an output frequency of zero. At positive full scale, the sum of the two currents will be 0.25 mA and the output will be at its maxi- mum frequency.
UNIPOLAR V/F, NEGATIVE INPUT VOLTAGE
Figure 3 shows the connection diagram for V/F conversion of negative input voltages. In this configuration full-scale output frequency occurs at negative full-scale input, and zero output frequency corresponds to zero input voltage. Figure 4. Connection Diagram for F/V Conversion, TTL Input
DECOUPLING
Decoupling power supplies at the device is good practice in any system, but absolutely imperative in high resolution applica- tions. For the ADVFC32, it is important to remember where the voltage transients and ground currents flow. For example, the current drawn through the output pull-down transistor originates from the logic supply, and is directed to ground through Pin 11 (Pin 8 of TO-100). Therefore, the logic supply should be decoupled near the ADVFC32 to provide a low im- pedance return path for switching transients. Also, if there is a separate digital ground it should be connected to the analog ground at the ADVFC32. This will prevent ground offsets that could be created by directing the full 8 mA output current into the analog ground, and subsequently back to the logic supply. Figure 3. Connection Diagram for V/F Conversion, Negative Input Voltage Although some circuits may operate satisfactorily with the power supplies decoupled at only one location on each board, this A very high impedance signal source may be used since it only practice is not recommended for the ADVFC32. For best results, drive the noninverting integrator input. Typical input imped- each supply should be decoupled with 0.1 µF capacitor at the ance at this terminal is 250 MΩ or higher. For V/F conversion ADVFC32. In addition, a larger board level decoupling capaci- of positive input signals the signal generator must be able to tor of 1 µF to 10 µF should be located relatively close to the source 0.25 mA to properly drive the ADVFC32, but for nega- ADVFC32 on each power supply. tive V/F conversion the 0.25 mA integration current is drawn from ground through R1 and R3.
COMPONENT TEMPERATURE COEFFICIENTS
Circuit operation for negative input voltages is very similar to The drift specifications of the ADVFC32 do not include tem- positive input unipolar conversion described in the previous perature effects of any of the supporting resistors or capacitors. section. For best operating results use component equations The drift of the input resistors R1 and R3 and the timing capaci- listed in that section. tor C1 directly affect the overall temperature stability. In the –4– REV. B
Input resistance RIN is composed of a fixed resistor (R1) and a
F/V CONVERSION
variable resistor (R3) to allow for initial gain error compensation. Although the mathematics of F/V conversion can be very com- To cover all possible situations, R3 should be 20% of RIN, and plex, the basic principle is easy to understand. Figure 4 shows R1 should be 90% of RIN. This allows a ± 10% gain adjustment the connection diagram for F/V conversion with TTL input to compensate for the ADVFC32 full-scale error and the toler- logic levels. Each time the input signal crosses the comparator ance of C1. threshold going negative, the one shot is activated and switches If more accurate initial offset is required, the circuit of R4 and 1 mA into the integrator input for a measured time period R5 can be added. R5 can have a value between 10 kΩ and (determined by C1). As the frequency increases, the amount of 100 kΩ, and R4 should be approximately 10 MΩ. The amount charge injected into the integration capacitor increases propor- of current required to trim zero offset will be relatively small, so tionately. The voltage across the integration capacitor is stabilized the temperature coefficients of these resistors are not critical. If when the leakage current through R1 and R3 equals the average large offsets are added using this circuit, temperature drift of current being switched into the integrator. The net result of both of these resistors is much more important. these two effects is an average output voltage which is propor- tional to the input frequency. Optimum performance can be
BIPOLAR V/F
obtained by selecting components using the same guidelines and By adding another resistor from Pin 1 (Pin 2 of TO-100 can) to equations listed in the V/F conversion section. a stable positive voltage, the ADVFC32 can be operated with a bipolar input voltage. For example, an 80 kΩ resistor to 10 V causes an additional current of 0.125 mA to flow into the inte- grator so that the net current flow to the integrator is positive even for negative input voltages. At negative full-scale input voltage, 0.125 mA will flow into the integrator from VIN cancel- ling out the 0.125 mA from the offset resistor, resulting in an output frequency of zero. At positive full scale, the sum of the two currents will be 0.25 mA and the output will be at its maxi- mum frequency.
UNIPOLAR V/F, NEGATIVE INPUT VOLTAGE
Figure 3 shows the connection diagram for V/F conversion of negative input voltages. In this configuration full-scale output frequency occurs at negative full-scale input, and zero output frequency corresponds to zero input voltage. Figure 4. Connection Diagram for F/V Conversion, TTL Input
DECOUPLING
Decoupling power supplies at the device is good practice in any system, but absolutely imperative in high resolution applica- tions. For the ADVFC32, it is important to remember where the voltage transients and ground currents flow. For example, the current drawn through the output pull-down transistor originates from the logic supply, and is directed to ground through Pin 11 (Pin 8 of TO-100). Therefore, the logic supply should be decoupled near the ADVFC32 to provide a low im- pedance return path for switching transients. Also, if there is a separate digital ground it should be connected to the analog ground at the ADVFC32. This will prevent ground offsets that could be created by directing the full 8 mA output current into the analog ground, and subsequently back to the logic supply. Figure 3. Connection Diagram for V/F Conversion, Negative Input Voltage Although some circuits may operate satisfactorily with the power supplies decoupled at only one location on each board, this A very high impedance signal source may be used since it only practice is not recommended for the ADVFC32. For best results, drive the noninverting integrator input. Typical input imped- each supply should be decoupled with 0.1 µF capacitor at the ance at this terminal is 250 MΩ or higher. For V/F conversion ADVFC32. In addition, a larger board level decoupling capaci- of positive input signals the signal generator must be able to tor of 1 µF to 10 µF should be located relatively close to the source 0.25 mA to properly drive the ADVFC32, but for nega- ADVFC32 on each power supply. tive V/F conversion the 0.25 mA integration current is drawn from ground through R1 and R3.
COMPONENT TEMPERATURE COEFFICIENTS
Circuit operation for negative input voltages is very similar to The drift specifications of the ADVFC32 do not include tem- positive input unipolar conversion described in the previous perature effects of any of the supporting resistors or capacitors. section. For best operating results use component equations The drift of the input resistors R1 and R3 and the timing capaci- listed in that section. tor C1 directly affect the overall temperature stability. In the –4– REV. B