Products

The Tabor 9160 Single-Channel Amplifier is a high-performance bench-top amplifier engineered for demanding lab and industrial applications. This 2U, half 19” rack-size amplifier provides a wide bandwidth of 45MHz and a high output of 34Vp-p into 50Ω, with peak currents up to 1A. Ideal for piezo-electronics, MEMS, and transducer testing, it combines precision, low distortion, and customizable configurations for gain, input impedance, and output setup.

Key Features

• Single-channel bench-top amplifier, 2U half 19” rack size
• DC-coupled wideband operation with 45MHz bandwidth
• High output voltage: up to 34Vp-p into 50Ω
• Peak output current: 1A, supporting up to 10W output power
• Fast transition time of <10ns for sharp signal edges
• Low distortion for accurate waveform reproduction
• Customizable gain (x10 standard, x15 optional), input impedance, and output configuration
• Front-panel main input with rear-panel auxiliary and DC offset inputs
• Ideal for piezo-electronics, MEMS, transducer characterization, and scientific applications
• Compact design compatible with standard lab setups

The 9200 Dual Amplifier from Tabor Electronics is a high-voltage, dual-channel amplifier engineered for precise signal amplification in laboratory, industrial, and scientific applications. Designed in a compact 2U half-rack format, it provides clean, high-fidelity amplification for signals from waveform, function, or pulse generators. With high voltage output, wide bandwidth, and flexible configuration, the 9200 Dual Amplifier is a versatile, cost-effective solution for demanding high-voltage applications.

Key Features

• High voltage output: 300Vp-p (±150V) per channel
• Output current: up to 100 mA per channel
• Full power bandwidth: DC to >500 kHz
• Slew rate: 200 V/µs for rapid signal transitions
• Dual-channel operation for simultaneous amplification
• Low distortion for precise waveform fidelity
• Customizable gain and signal ground options
• Floating input and output for flexible grounding
• Compact 2U bench-top or rack-mountable design
• Cost-effective high-voltage amplification solution

The 9200A Dual Amplifier from Tabor Electronics is a high-voltage, dual-channel amplifier engineered for precision signal amplification. With compact design and advanced safety features, it supports versatile applications from laboratory testing to MEMS actuator control. Built to maintain signal fidelity across wide bandwidths, the 9200A offers reliable, low-distortion amplification for critical high-voltage applications.

Key Features

• Dual independent channels with precise amplification
• High voltage output: 400Vp-p (±200V) per channel
• Output current: up to 100 mA per channel
• Full power bandwidth: DC to >500 kHz
• High slew rate: 400 V/µs for fast signal transitions
• Rear-panel monitor outputs for each channel
• Compatible with all Tabor waveform generators
• Special unipolar mode for MEMS engine drivers
• Compact, stackable 2U chassis for bench-top or rack mounting
• Advanced safety latch and front panel high voltage switch

The Tabor 9250 Dual-Channel Amplifier is a high-performance, bench-top amplifier designed for lab and PXI-based test systems. It provides two independent channels or a single differential output with precise amplification up to 40Vp-p. With large and small signal bandwidths up to 30MHz, a high slew rate of 200V/µs, and low distortion, the 9250 is ideal for waveform amplification and high-fidelity signal testing.

Key Features

• Dual-channel bench-top amplifier, 2U half 19” rack size
• Operates as independent channels or single differential output
• Large signal bandwidth: 15MHz, small signal bandwidth: 30MHz
• High amplitude output: up to 40Vp-p into high impedance
• Slew rate up to 200V/µs for fast signal transitions
• Low distortion for precise waveform reproduction
• Configurable gain, input impedance, output impedance, and output configuration
• Additional rear-panel inputs for DC offset and signal summation
• Stackable design compatible with other Tabor generators and PXI setups
• Front-panel outputs for easy access and measurement

The Tabor 9260 Dual-Channel Amplifier is a versatile bench-top amplifier designed for high-frequency, high-current signal applications. Its 2U, half 19” rack design delivers up to 34Vp-p output into 50Ω and peak currents up to 1A. The 9260 can operate as two independent channels or one input with two differential outputs, making it perfect for piezo-electronics, MEMS, and transducer testing. Customizable gain, input impedance, and output configurations provide unmatched flexibility for demanding lab environments.

Key Features

• Dual-channel bench-top amplifier, 2U half 19” rack size
• DC-coupled wideband operation with 45MHz bandwidth
• High output voltage: up to 34Vp-p into 50Ω
• Peak output current: 1A, supporting up to 10W output power
• Fast transition time of <10ns for precise signal edges
• Low distortion for accurate waveform reproduction
• Configurable gain (x10 standard, x15 optional), input impedance, and output setup
• Front-panel main input; rear-panel auxiliary and DC offset inputs
• Operates as independent channels or differential output mode
• Ideal for piezo-electronics, MEMS, transducer characterization, and scientific applications

The 9400 Four Channel Amplifier from Tabor Electronics is a compact, high voltage signal amplifier built for precision and flexibility. Designed with four fully independent channels, it delivers powerful 400Vp-p output while maintaining exceptional signal integrity across a wide bandwidth. Ideal for laboratory testing, MEMS actuator control, and high voltage research applications, this amplifier combines performance, safety, and space-saving design in one reliable solution.

Key Features

• Four independent amplification channels
• High voltage output up to 400Vp-p (±200V)
• Output current up to 50mA per channel
• Full power bandwidth from DC to over 500kHz
• High slew rate up to 400V per microsecond
• Rear panel monitor outputs divided by 100
• Compatible with Tabor waveform generators
• Special unipolar mode for MEMS engine drivers
• Compact chassis for bench-top stacking or 19 inch rack mounting
• Advanced safety latch and high voltage mechanical switch

The Tabor A10150 Signal Amplifier is a compact, high-speed amplifier designed to enhance any signal source. With 150MHz bandwidth and up to 20Vp-p output into 50Ω, it provides clean, low-distortion amplification. Its ultra-fast transition time of under 1.8ns ensures precise waveform fidelity, making it ideal for Ethernet testing, ASIC, FPGA, and DAC characterization. The A10150 can be used as a standalone amplifier or as a “Snap-On” accessory for Tabor WaveXciter and WS8351/2 models, extending signal voltage without compromising integrity.

Key Features

• Single-channel, DC-coupled wideband amplifier
• High bandwidth of 150MHz for fast signal response
• Maximum output up to 20Vp-p into 50Ω load
• Ultra-fast transition time: <1.8ns for precise waveform edges
• Compact, all-metal footprint for easy integration
• Low distortion ensures clean signal amplification
• Custom gain options: x5 standard, x10 optional
• Compatible with Tabor WaveXciter and WS8351/2 series
• Suitable for Ethernet, FPGA, ASIC, and DAC testing

The Tabor A10160 Signal Amplifier is a compact, high-current amplifier designed to boost any signal source with precision. Offering 45MHz bandwidth, up to 34Vp-p output into 50Ω, and 10W peak power, it ensures clean, low-distortion signals. Its ultra-fast transition time of under 10ns delivers sharp waveform edges, making it ideal for piezo-electronics, transducer testing, MEMS, and general high-speed electronic applications. The A10160 can operate as a standalone amplifier or as a “Snap-On” accessory for Tabor WaveXciter and WS8351/2 series, providing flexible, cost-effective power enhancement.

Key Features

• Single-channel, DC-coupled wideband amplifier
• 45MHz high-speed bandwidth for fast signal response
• Maximum output of 34Vp-p into 50Ω
• High output current drive up to 1A
• Peak power up to 10W, continuous power 7.5W
• Ultra-fast transition time: <10ns
• Compact, all-metal footprint for lab and bench setups
• Low distortion for precise signal amplification
• Custom gain options: x10 standard, x15 or x20 optional
• Compatible with Tabor WaveXciter and WS8351/2 series

The A10200 RF Signal Amplifier from Tabor Electronics is a high-power, ultra-wideband amplifier designed for demanding high-frequency applications. Compact and versatile, it extends the output power of any signal source up to +28dBm across 100 kHz to 20 GHz, providing a reliable solution for RF testing, multi-tone experiments, and advanced electronics applications.

Key Features

• Ultra-wideband frequency range: 100 kHz to 20 GHz
• High output power: +28dBm typical at P1dB
• Reverse polarity and over/under voltage protection
• Compact, lightweight design with dedicated power supply
• Ideal for high-frequency RF and signal testing
• Compatible with Tabor Lucid series generators or any signal source
• Maintains signal integrity across full bandwidth
• Cost-effective, versatile solution for laboratory and field applications

The AH401D Picoammeter is a compact and high precision 4 channel charge integration electrometer designed for accurate low current measurements. Built with an advanced charge integration input stage and a 20 bit delta sigma ADC, the instrument ensures reliable sensing of extremely small currents with minimal noise. Its simultaneous multi channel sampling, Ethernet connectivity, and trigger input make it a powerful solution for beam monitoring, detector measurements, and scientific instrumentation. The AH401D is engineered for stable performance, high linearity, and precise signal acquisition in demanding laboratory environments.

Key Features

• 4 channel simultaneous sampling picoammeter
• Advanced charge integration input stage for precise current sensing
• 20 bit delta sigma ADC with digital noise reduction filter
• Eight selectable input current ranges
• Measurement ranges from 50 pA up to 2 µA
• Ultra high resolution down to 50 aA
• User selectable integration time from 1 ms to 1 s
• Continuous current to voltage conversion without dead time
• Ethernet interface with TCP/IP and UDP communication
• External trigger input for synchronized measurements
• Compact low noise design for close placement to signal sources
• Plug and play oscilloscope software for configuration and analysis

The AH501D Picoammeter is a high performance 4 channel bipolar electrometer designed for precise low current measurements in advanced research and detector monitoring systems. Built with a transimpedance input stage and high resolution 24 bit conversion, the instrument delivers accurate simultaneous current measurements across multiple channels. With an integrated bias voltage source, analog monitoring outputs, and Ethernet connectivity, the AH501D provides a complete solution for beam position monitoring, detector analysis, and scientific instrumentation.

Key Features

• 4 channel simultaneous sampling bipolar picoammeter
• 24 bit high resolution current measurement
• Three selectable input current ranges
• Bipolar current measurement capability
• Measurement range from ±2.5 nA up to ±2.5 mA
• Ultra high resolution down to 300 aA
• Fast sampling with minimum period of 38.4 microseconds
• Integrated low noise bias voltage source up to 30 V
• Analog monitor outputs for real time signal observation
• Ethernet interface with TCP/IP and UDP communication
• External trigger and gate input for synchronized acquisition
• Compact design to reduce cable noise interference
• Plug and play oscilloscope software for configuration and analysis

The AMC-PICO-8 Picoammeter is a high performance 8 channel bipolar electrometer designed for precision current measurements in advanced instrumentation environments. Built in the MTCA.4 format, the device combines a specialized transimpedance input stage with 20 bit simultaneous sampling ADCs to deliver fast and accurate current sensing. With sampling speeds up to 1 MSPS and floating input capability up to ±300 V, the system supports demanding detector readout and scientific measurement applications. Its FPGA based signal processing and PCI Express communication ensure reliable data acquisition and efficient system integration.

Key Features

• 8 channel simultaneous bipolar current measurement
• High resolution 20 bit analog to digital conversion
• Sampling rate up to 1 MSPS for fast data acquisition
• MTCA.4 Advanced Mezzanine Card architecture
• Floating input capability up to ±300 V relative to chassis ground
• Transimpedance input stage with advanced signal conditioning
• Multiple selectable measurement ranges depending on configuration
• Integrated FPGA for high speed signal processing
• Digital channel calibration with onboard EEPROM storage
• Trigger based acquisition with pre trigger memory capture
• PCI Express communication interface for system control
• Scatter gather DMA support for high speed data transfer

The BatReg² Battery Cycler is a high-precision bidirectional and regenerative battery testing system designed for advanced battery research, cycling, and charging applications. Built with state-of-the-art digital control and regenerative technology, it enables accurate testing while efficiently returning excess energy to the grid. With output ratings up to 100 V and ±150 A, this system delivers reliable performance for laboratories, research centers, and battery development facilities.

Key Features

• High-precision bidirectional and regenerative battery cycler
• Output capability up to 100 V and ±150 A
• Multiple regulation modes including Constant Voltage, Constant Current, and Constant Power
• 24-bit resolution at 100 kHz for precise output setting and readback
• Built-in polarity detection for safe battery connection
• Embedded web server interface for monitoring and configuration
• Integrated 24-bit Arbitrary Waveform Generator running at 100 kHz
• 4-channel precision oscilloscope for advanced signal monitoring
• High efficiency regenerative design that returns energy to the grid
• Low output noise and ripple due to high switching frequency architecture
• Ethernet connectivity supporting TCP/IP and UDP communication
• Optional trigger, analog control, auxiliary ADC, and K-type thermocouple inputs

Key Features:

• Wide frequency range: 9 kHz – 8 GHz
• High gain: 29 dB up to 6 GHz, 27 dB from 6 – 8 GHz
• Low noise figure: < 2.7 dB @ 1 GHz
• Compact aluminum housing (85 × 36 × 29 mm, 130 g)
• ESD-protected input for safe operation
• Operates on simple +12 V DC power supply
• Rugged and lightweight design for field and lab use

The BEST Beam Stabilization System is a complete turnkey solution designed to control and stabilize photon beam position and intensity in synchrotron radiation X ray beamlines. Developed to support high precision beamline experiments, the system integrates advanced hardware with powerful software tools to deliver reliable beam monitoring and correction. With a distributed architecture and FPGA driven control algorithms, the BEST system allows researchers to optimize beam stability, improve experimental accuracy, and maintain consistent beam performance in demanding scientific environments.

Key Features

• Complete turnkey system for photon beam position and intensity stabilization
• Designed for synchrotron radiation X ray beamline applications
• Simultaneous control of beam position X and Y and beam intensity I0
• Distributed architecture for flexible installation near beamline components
• High speed FPGA based hardware for low latency correction performance
• Advanced control algorithms operating across several kHz frequency range
• Integrated readout unit based on high precision picoammeter technology
• Dedicated control and interface unit for system configuration and monitoring
• Gigabit Ethernet connectivity for network integration
• High throughput communication interface for real time system control
• Compatible with EPICS based beamline control systems
• Software tools for detector configuration and beamline optimization

A modular, scalable, and intelligent matrix switching system designed for precision in multi-channel test applications.

Key Features:

• Modular design with up to 4 plugin switch cards
• 6×32 channel matrix, up to 2A per channel
• Remote control via TCP/IP interface
• Integrated diagnostics & safety monitoring
• Compatible with LabView, Python, C++, CANoe, and more
• Auto-cooling with smart fan activation
• Rack-mountable 4HU chassis with high build quality
• Expandable switching lines with CU-600 matrix
• Unlimited waveform size with dual waveform output
• Protocol generation and oscilloscope waveform simulation