5725A

Instruction Manual

Integrator

4-42.

Op amp U601A is configured as an integrator to reduce the output offset of the input amplifier circuit. This integrator senses the output voltage of the amplifier (MVOUT) through R604 and R605 and forces it to be zero with respect to HVCOMM.

Window Comparator

4-43.

Comparators U604A and U604B form a window comparator that monitors the output of the input amplifier, U602. The window is set to about +2.2V to +9V by R626, VR602, and R636. If the output of U602 exceeds the window limits, the appropriate comparator turns on the clamp, Q604, shorting the input to ground. The comparator also pulls control line CLAMPS high via U604D, where the comparator routes to the Digital Assembly (A5) through the Interconnect assembly (A1). Comparator U604D is a level shifter to translate the window comparator output to a TTL level.

Exceeding the limits of the window comparator is an indication that the loop is in an abnormal condition when the instrument is in the ac voltage standby or ac voltage operate states. In current standby or current operate states, the comparator causes CLAMPS to be asserted, which turns off the +400V and -400V supplies.

Input Clamp

4-44.

A FET clamp, Q604, is turned on until the output of U602 returns to the region within the window. When this occurs, the comparator turns off Q603. To avoid a large transient at the output of the High Voltage Amplifier assembly (A6), the clamp must be turned off slowly. Resistor R637 and C618 slow the clamp drive signal to accomplish this. Though Q604 can be turned off slowly by removing its gate drive slowly, it clamps asymmetrically in the transition region. The body of the FET is held at -7.5V. This keeps the FET from turning on at the negative peaks of the input waveform. The asymmetrical clamping appears as a dc shift in the waveform, which can cause the transformer to saturate. To alleviate this problem, a second clamp is placed in parallel with Q604.

This second clamp is the photoresistor portion of the optical isolator, U605. It has a considerably higher on resistance than Q604, so the two are used together. When the clamp is to be turned off, Q603 is turned off and the voltage on C618 begins its transition from nearly +15V to -15V. At +15V, Q604 is turned on but because Q605 is also on, shunting current from the input of U605, the photoresistor is in the high impedance state. When the voltage on C618 reaches about +9V, Q605 turns off and the optoisolator is turned on, putting the photoresistor into its low resistance state. This has little effect on the input signal because the photoresistor is a higher impedance than the FET. As the control voltage approaches zero, Q604 turns off and the input is clamped only by the photoresistor. As the control voltage continues toward -15V, the photoresistor makes the transition to its off, or high impedance state. The photoresistor clamps symmetrically, eliminating the dc transient on the input. A similar transition takes place when light turns on the clamp but it happens much faster, as the turn-on transition is controlled by the time constant R631*C618 which is about an order of magnitude faster than the R637*C618 turn-off time constant.

The microprocessor on the Digital assembly can also pull the clamp via control line CLAMPD, which is latched into a driver on the High Voltage Sense assembly (A6). Line CLAMPD is asserted during a sequenced turn on, power down of the High Voltage Amplifier assembly (A3), or during a transition to another frequency range. Comparator U604C level shifts CLAMPD and provides an OR function with the window comparator output.

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Fluke 5725A instruction manual Integrator, Window Comparator, Input Clamp

5725A specifications

The Fluke 5725A is a high-performance, multifunctional temperature calibration source designed to meet the demanding requirements of laboratory and industrial environments. Renowned for its accuracy, reliability, and versatility, the 5725A serves as a powerful tool for engineers and technicians engaged in temperature calibration processes.

At the core of the 5725A is its advanced measurement technology, which allows for precision temperature calibrations across a wide range. With an operating temperature range from -200°C to 660°C, it caters to various applications, making it suitable for calibrating thermocouples, resistance temperature detectors (RTDs), and other temperature measurement devices.

One of the standout features of the Fluke 5725A is its outstanding accuracy, boasting a specified uncertainty of just ±0.15°C. This level of precision ensures that users can maintain compliance with regulatory standards and regulatory requirements in fields such as aerospace, pharmaceuticals, and manufacturing.

The Fluke 5725A is equipped with dual-channel capabilities, allowing users to calibrate two devices simultaneously. This enhances productivity by minimizing downtime and optimizing workflow efficiency. The intuitive touchscreen interface simplifies operations, enabling users to view measurements, set up test parameters, and access historical data with ease.

Versatile connectivity options such as USB and Ethernet enable seamless integration into existing systems and allow for data transfer, remote control, and configuration. This feature empowers technicians to conduct calibrations efficiently, whether on-site or remotely.

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Another notable characteristic of the 5725A is its ability to generate stable temperature outputs with minimal drift, contributing to consistency in calibration results. Its built-in self-test functionality helps ensure that the unit remains in peak operating condition, giving users confidence in their calibration processes.

In summary, the Fluke 5725A is a top-tier temperature calibration source that excels in accuracy, reliability, and user-friendliness. Whether in laboratory settings or industrial applications, its advanced technologies and features make it an essential tool for professionals tasked with maintaining precision in temperature measurements.