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LMH6612MA Datasheet, PDF (27/32 Pages) Texas Instruments – Single Supply 345 MHz Rail-to-Rail Output Amplifiers
DC LEVEL SHIFTING
Often a signal must be both amplified and level shifted while
using a single supply for the op amp. The circuit in Figure 9
can do both of these tasks. The procedure for specifying the
resistor values is as follows.
1. Determine the input voltage.
2. Calculate the input voltage midpoint, VINMID = VINMIN +
(VINMAX – VINMIN)/2.
3. Determine the output voltage needed.
4. Calculate the output voltage midpoint, VOUTMID =
VOUTMIN + (VOUTMAX – VOUTMIN)/2.
5. Calculate the gain needed, gain = (VOUTMAX – VOUTMIN)/
(VINMAX – VINMIN)
6. Calculate the amount the voltage needs to be shifted
from input to output, ΔVOUT = VOUTMID – gain x VINMID.
7. Set the supply voltage to be used.
8. Calculate the noise gain, noise gain = gain + ΔVOUT/VS.
9. Set RF.
10. Calculate R1, R1 = RF/gain.
11. Calculate R2, R2 = RF/(noise gain-gain).
12. Calculate RG, RG= RF/(noise gain – 1).
Check that both the VIN and VOUT are within the voltage
ranges of the LMH6611.
4th ORDER MULTIPLE FEEDBACK LOW-PASS FILTER
Figure 10 shows the LMH6612 used as the amplifier in a mul-
tiple feedback low pass filter. This filter is set up to have a gain
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FIGURE 9. DC Level Shifting
The following example is for a VIN of 0V to 1V with a VOUT of
2V to 4V.
1. VIN = 0V to 1V
2. VINMID = 0V + (1V – 0V)/2 = 0.5V
3. VOUT = 2V to 4V
4. VOUTMID = 2V + (4V – 2V)/2 = 3V
5. Gain = (4V – 2V)/(1V – 0V) = 2
6. ΔVOUT = 3V – 2 x 0.5V = 2
7. For the example the supply voltage will be +5V.
8. Noise gain = 2 + 2/5V = 2.4
9. RF = 2 kΩ
10. R1 = 2 kΩ/2 = 1 kΩ
11. R2 = 2 kΩ/(2.4-2) = 5 kΩ
12. RG = 2 kΩ/(2.4 – 1) = 1.43 kΩ
of +1 and a −3 dB point of 1 MHz. Values can be determined
by using the WEBENCH® Active Filter Designer found at
www.amplifiers.national.com.
www.national.com
FIGURE 10. 4th Order Multiple Feedback Low-Pass Filter
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