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Amplifier Circuit

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20_W_450_MHz_AMPLIFIER

Published:2009/6/18 1:41:00 Author:May

20_W_450_MHz_AMPLIFIER
Delivering 20-W output, this amplifier has a gain of 21 dB at 450 MHz. A 12-V supply powers this circuit.   (View)

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30_MHz_AMPLIFIER

Published:2009/6/18 1:40:00 Author:May

30_MHz_AMPLIFIER
Using a CLC406 op amp, this video amplifier has a voltage gain of +2 and is flat to 30 MHz. The circuit should be useable in video switching and interfacing applications.   (View)

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MINIATURE_WIDEBAND_AMPLIFIER

Published:2009/6/17 23:39:00 Author:May

MINIATURE_WIDEBAND_AMPLIFIER
Except for the coupling and decoupling capacitors, IC1 is a complete wideband amplifier that has a fixed gain of 20 dB to 450 MHz. No external compensation is required.   (View)

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70_MHz_RF_POWER_AMPLIFIER

Published:2009/6/17 23:38:00 Author:May

70_MHz_RF_POWER_AMPLIFIER
The SD1143 transistor provides a gain of about 14 dB in this circuit. It uses the fact that a 175-MHz device has a much higher gain when used at lower frequencies. The amplifier was originally de-signed to be used with a transverter. The output is 8 to 10 W for a 300- to 500-mW input.   (View)

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BROADCAST_BAND_RF_AMPLIFIER

Published:2009/6/17 23:36:00 Author:May

BROADCAST_BAND_RF_AMPLIFIER
The circuit has a frequency response that ranges from lO0 Hz to 3 MHz; the gain is about 30 dB. Field-effect transistor Q1 is configured in the common-source self-biased mode; optional resistor R1 allows you to set the input impedance to any desired value. Commonly, it will be 50 Ω. The signal is then direct-coupled to Q2, a common-base circuit that isolates the input and output stages and pro-vides the amplifier's exceptional stability. Last, Q3 functions as an emitter-follower, to provide low output impedance (about 50 Ω). If you need higher output impedance, include resistor R8. It will af-fect impedance according to this formula:R8≈ROUT - 50. Otherwise, connect output capacitor C4 directly to the emitter of Q3.   (View)

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LOW_NOSIE_GASFET_PREAMP_FOR_435_MHz

Published:2009/6/17 23:21:00 Author:May

LOW_NOSIE_GASFET_PREAMP_FOR_435_MHz
This circuit is a low-noise preamplifier for the 435-MHz amateur satellite frequencies. The cir-cuit uses a Mitsubishi MGF1302. A 28-Vdc source is shown, although by changing the 400-Ω 5-W re-sistor lower voltages can be used.   (View)

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BROADBAND_RF_AMPLIFIER

Published:2009/6/17 23:19:00 Author:May

BROADBAND_RF_AMPLIFIER
The use of a FET gives this amplifier a high input impedance. The bandwidth should be ade-quate for LW through HF use (dc-30 MHz), as an active antenna preamplifier.   (View)

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VHF_UHF_PREAMP_USING_MAR_x

Published:2009/6/17 23:17:00 Author:May

VHF_UHF_PREAMP_USING_MAR_x
The MAR-x preamp shown will cover up to 1.5 or 2 GHz with the correct MAR-x IC. ATTN1 should be omitted for low noise-figure applications. ATTN1 and ATTN2 provide a means of lirniting possible termination range, for less chance of device instability.   (View)

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BUFFER_ISUP2_SUPC_DATA_AND_CLOCK_LINES

Published:2009/6/17 3:15:00 Author:May

BUFFER_ISUP2_SUPC_DATA_AND_CLOCK_LINES
The I2C serial bus is a popular two-wire bus for small-area networks. I2C Clock and Data lines have open collector (or drain) outputs for each device on the network. Only a single pull-up resistor is needed. With this architecture, each device can talk on the network, rather than just listen. In some circumstances, it might be desirable to buffer these lines to expand the network, which can sometimes be a tricky task. The obvious approach (Fig. 1) wont work because it latches in either the higher or lower state. A circuit for a noninventory nonlatching buffer is also shown.The circuit is symmetrical about its center so that the input and output can be swapped. Q1 and Q8 are the output open collector drivers. Q2, Q3, Q6, and Q7 provide the nonlatching functions. The capacitors prevent switching glitches by ensuring the inhibit transistors tum off before the output transistors do.Operation can be best explained by example: if the input is high, Q4 turns off, and the voltage across R8 goes to zero. This tums off Q1 and Q8. The output then goes high, which is the circuit's normal resting place. If the input is pulled Iow, Q4 is tumed on.Diode D1 remains reverse-biased, preventing Q3 from tuming off Q4. With Q4 on, current is sup-plied to both Q2 and Q1 to turn them on, but Q2 turns on first to keep Q1 off. This prevents the in-put from latching. Q4 also turns on Q8. D4 is now forward-biased, so Q6 tums on, and thus tums off Q5. With Q5 off, Q7 will not tum on. The output remains low. Even with both the input and the out-put extemally driven low, the circuit will not latch. The circuit, using the values shown in Fig. 2, reached a clock rate of 80 kHz with a VOH of 5.0 V and a VOL of 0.5 V.   (View)

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LOW_OFFSET_SIMPLE_VIDEO_BUFFER

Published:2009/6/17 2:13:00 Author:May

LOW_OFFSET_SIMPLE_VIDEO_BUFFER
This circuit has proved to be an effective video buffer and will easily drive a 75-Ω load to 1.5-V p-p output. BW is better than 20 MHz and there is less than 0.05-V dc offset, which is the difference inVBE of Q1 and Q2. The supply lines should be well bypassed, ± 5V or more.   (View)

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3_V_RAIL_TO_RAIL_SINGLE_SUPPLY_BUFFER

Published:2009/6/17 2:11:00 Author:May

3_V_RAIL_TO_RAIL_SINGLE_SUPPLY_BUFFER
The LMC6484 provides a 3-V p-p rail-to-rail buffer with a +3-V supply commonly used for logic systems.   (View)

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SIMPLE_VIDEO_BUFFER

Published:2009/6/17 2:10:00 Author:May

SIMPLE_VIDEO_BUFFER
This simple emitter follower can be used as a video buffer.   (View)

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MOSFET_BUFFER_AMPLIFIER

Published:2009/6/17 2:09:00 Author:May

MOSFET_BUFFER_AMPLIFIER
A MOSFET is used as a wideband buffer amplifier. T1 is wound on a toroid of approximately 1/2 diameter, with material suitable for frequency (usually 1- to 20-MHz range). The turns ratio should be about 4:1 depending on load imped-ance. Typically, at 4 MHz, there are 18 turns on the primary, 4 turns on the secondary, and the stage gain is about 14-dB voltage (ZL = 50 Ω).   (View)

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VFO_BUFFER_AMPLIFIER

Published:2009/6/17 2:06:00 Author:May

VFO_BUFFER_AMPLIFIER
A two-transistor feedback pair provides broadband operation. The gain is approximately R4/R1.   (View)

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HIGH_CURRENT_BUFFER

Published:2009/6/17 2:03:00 Author:May

HIGH_CURRENT_BUFFER
By parallel connecttng all six gates of this 4049 hex inverting buffer,you can obtain a much higher output current than would othewise be available.   (View)

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BUFFER_AMPLIFIERS

Published:2009/6/17 2:00:00 Author:May

BUFFER_AMPLIFIERS
These two buffer/amplifiers that have been successfully used with VFOs: one (shown in A) is based on a pair of bipolar npn transistors, and the other (shown in B) is built around a dual-gate MOSFET.   (View)

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LM6218_HIGH_SPEED_INSTRUMENTATION_AMPLIFIER

Published:2009/6/16 22:53:00 Author:May

LM6218_HIGH_SPEED_INSTRUMENTATION_AMPLIFIER
This amplifier features 400-μsec settling time (to 0.01%), 140-V/psec slow rate, and 17-MHz gain-bandwidth product. The supply voltage can be ±5 to ±20V.   (View)

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LMC6062_INSTRUMENTATION_AMPLIFIER

Published:2009/6/16 22:41:00 Author:May

LMC6062_INSTRUMENTATION_AMPLIFIER
Useful for +5-V single-supply applications, this op amp circuit features low drain (around 1 mA), high input resistance (1014Ω), and low bias current (≈10-14A).   (View)

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NONINVERTING_ac_AMPLIFIER

Published:2009/6/15 2:32:00 Author:May

NONINVERTING_ac_AMPLIFIER
A general-purpose noninverting ac amplifier for audio of other low-frequency applications is shown. Design equations are in the figure. Almost any general-purpose op amp can be used for U1.   (View)

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AUDIO_DISTRIBUTION_AMPLIFIER

Published:2009/6/15 23:13:00 Author:May

AUDIO_DISTRIBUTION_AMPLIFIER
Three low-Z audio outputs are available from this circuit, using a quad TL084 FET amplifier. The input is high impedance. VCC can be 6 to 12 V for typical applications.   (View)

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