For the most demanding DC and AC applications
Lake Shore combined the technical advantages of digital signal processing with over a decade of experience in precision magnetic field measurements to produce the first commercial digital signal processor (DSP) based Hall effect gaussmeter, the Model 475.
DSP technology creates a solid foundation for accurate, stable, and repeatable field measurement while simultaneously enabling the gaussmeter to offer an unequaled set of useful measurement features. The Model 475 is intended for the most demanding
DC and AC applications. In many cases, it provides the functionality of two or more instruments in a field measurement system.
The power of DSP technology is demonstrated in the superior performance of the Model 475 in DC, RMS, and Peak measurement modes.
Advanced features
The Model 475 combines hardware and firmware elements to create advanced features that facilitate automation and materials analysis.
Field control
A built-in PI control algorithm turns the 475 into an essential building block for magnetic field control in electromagnet systems. It, along with a voltage-programmable magnet power supply, is all that is needed to control stable magnetic fields
in an electromagnet at the user-specified setpoint. One of the built-in analog voltage outputs drives the program input of the power supply for either bipolar or unipolar operation.
High-speed data transfer
The IEEE-488 interface can be set to send readings in binary format rather than the more common ASCII format. This reduces interface overhead, enabling real-time reading rates up to 100 new readings per second. Temperature compensation is not available
at the highest interface rate.
Data buffer
Internal memory provides storage for 1,024 field readings in a data buffer. The buffer can be filled at high speed, up to 1,000 readings per second, which is as much as ten times faster than the computer interface. Stored readings can then be retrieved
over interface at slower speed and processed offline. A trigger input can be used to initiate the data log sequence. Slower sample rates can be programmed if desired.
Trigger in and trigger out
A TTL-level hardware trigger into the instrument can be used to initiate the data log sequence. A TTL-level hardware trigger out indicates when the instrument completes a reading and can be used to synchronize other instruments in the system. An IEEE-488
software-based trigger can be used like the hardware trigger in.
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