Using the THS4012 EVM In The Noninverting Mode

1.4 Using the THS4012 EVM In The Noninverting Mode

The THS4012 EVM operates from power-supply voltages ranging from ± 5 V to ± 15 V. As shipped, the EVM is configured for inverting operation and the gain is set to 4. Signal inputs on the module are terminated for 50-Ωnominal source impedance. An oscilloscope is typically used to view and analyze the EVM output signal.

1)Ensure that all power supplies are set to OFF before making power supply connections to the THS4012 EVM.

2)Connect the power supply ground to the module terminal block (J2) location marked GND.

3)Select the operating voltage for the EVM and connect appropriate split power supplies to the module terminal block (J2) locations marked ±VCC and +VCC.

4)Connect an oscilloscope to the module SMA output connector (J3/J5) through a 50-Ωnominal impedance cable (an oscilloscope having a 50-Ω

input termination is preferred for examining very high frequency signals).

5)Set the power supply to ON.

6)Connect the signal input to the module SMA input connector (J1/J4).

Each EVM input connector is terminated with a 50-Ωimpedance to ground. With a 50-Ωsource impedance, the voltage seen by the THS4012 amplifier IC on the module will be ￿the source signal voltage applied to the EVM. This is due to the voltage division between the source impedance and the EVM input terminating resistors (R1, R9).

7) Verify the output signal on the oscilloscope.

The signal shown on an oscilloscope with a 50-Ωinput impedance will be ￿ the actual THS4012 amplifier IC output voltage. This is due to the voltage division between the output resistor (R7, R15) and the oscilloscope input impedance.

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General

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Texas Instruments manual Using the THS4012 EVM In The Noninverting Mode

THS4012 specifications

The Texas Instruments THS4012 is a high-performance, dual-channel operational amplifier designed for a wide variety of applications requiring high speed and precision. This op-amp is particularly appreciated in the fields of signal processing, data acquisition, and instrumentation, thanks to its exceptional characteristics and innovative technologies.

One of the standout features of the THS4012 is its ultra-low input noise and high slew rate, which make it a compelling choice for applications that demand rapid response times without signal distortion. With a slew rate of up to 1200 V/µs, the THS4012 can handle rapid changes in input signals, making it ideal for high-frequency applications such as analog-to-digital converters and RF signal processing.

In terms of performance, the THS4012 boasts a wide bandwidth of approximately 100 MHz at a gain of 1, ensuring it can efficiently transmit fast signals without significant loss. The part also provides a high common-mode rejection ratio (CMRR) and power supply rejection ratio (PSRR), enhancing its stability in environments with fluctuating power supply conditions or varying signal levels.

Another important aspect of the THS4012 is its low total harmonic distortion (THD), which is crucial for high-fidelity applications. By minimizing distortions, it ensures that the output signal closely matches the input signal, preserving the integrity of the original waveform. This makes it especially suitable for audio applications and precision data acquisition systems.

The THS4012 operates on a single or dual power supply, with a voltage range from ±2.5 V to ±6 V, providing designers with the flexibility to integrate this op-amp into various circuit configurations. The device is available in compact packages, making it suitable for space-constrained designs in portable electronics.

Additionally, the THS4012 incorporates innovative features such as internal compensation, which simplifies the design process by reducing the need for external components. This enhances design efficiency and reliability, allowing engineers to focus on other critical aspects of their circuits.

In conclusion, the Texas Instruments THS4012 dual operational amplifier combines high-speed performance, low distortion, and flexible power supply options, making it a popular choice for engineers looking to enhance the capabilities of their electronic systems. Its advanced technologies and characteristics render it a strong option in a myriad of applications within today's demanding electronic landscape.