Products

Precision, performance, and scalability packed into a high-efficiency DC power solution. Ideal for demanding test environments and energy recovery.

Key Features:

• Output voltage: 0–240 V DC
• Scalable from 27 kW to 2000+ kW
• Modular build: up to 44 connected units
• Full sink/source operation with regeneration
• Ultra-fast switching: rise/fall time <250 µs
• Accuracy: <0.02% FS with high-res current range
• Auto-ranging capability (factor of 3)
• Control modes: CV, CC, CP, CR, Ri-Sim
• Seamless waveform generation via AnyWave + WaveMaster
• Optional HMI touchscreen and CAN interface

Precision meets performance in this regenerative, modular, and highly controllable DC power supply for high-voltage testing applications.

Key Features:

• Output voltage: 0 to 3000 V DC
• Power range: 54 to 2000+ kW
• Fast response: <250 µs rise/fall times
• Regenerative sink/source operation
• High current accuracy: <0.02% FS
• Auto-ranging voltage-current flexibility (factor 3)
• Full digital modes: CV, CC, CP, CR, Ri-Sim
• Modular design with up to 44 units
• Optional HMI touchscreen and CAN interface
• Waveform generation via AnyWave + WaveMaster

High-speed, modular AC power supply with precision control and full regeneration. Perfect for grid simulation, HIL testing, and EMC validation.

Key Features:

• Power scalable from 30 kVA to 1050+ kVA
• Voltage range: 0–305 V AC with 4 active outputs
• True 4-quadrant regenerative design for energy efficiency
• Ultra-fast switching time (≤200 µs response)
• High current accuracy <0.02% full scale
• Full digital control modes: CV, CC, CP, CR, Ri-Sim
• Programmable grid simulator, AC amplifier, or electronic RLC load
• Compatible with AnyWave & WaveMaster for custom waveform control
• Modular 19” rack-mounted units with low heat and noise output
• Ideal for automotive, aerospace, HIL, EMC, and renewable power testing

A precision-driven, regenerative DC power supply ideal for high-demand testing environments across industries.

Key Features:

• Voltage range: 0 to 320 V DC
• Power output: 36 to 2000+ kW
• Modular and scalable up to 44 units
• Regenerative sink and source operation
• Voltage rise/fall time <250 µs
• Accuracy <0.02% FS with high-res current range
• Auto-ranging factor of 3
• Full digital control: CV, CC, CP, CR, Ri-Sim
• Supports AnyWave + WaveMaster waveform control
• Optional touchscreen HMI and CAN interface

Key Features:

• Dual-channel arbitrary waveform generation with 2.8 MS/s sampling rate and 16-bit resolution.
• Integrated with BOLAB WaveMaster software for graphical and tabular waveform design.
• Endless waveform streaming with double buffer memory for uninterrupted operation.
• Real-time triggering, data acquisition, and live waveform editing.
• Supports importing oscilloscope data, ASCII, and TDMS files.
• Preloaded waveform libraries for LV 124, LV 148, ISO 7637-2, ISO 16750-2, GMW, JLR, VW standards.
• Seamless integration with LabView, Python, CANoe, MATLAB, C/C++ via DLLs.
• Compact and robust design for laboratory and industrial testing applications.

High-efficiency regenerative DC power supply with scalable architecture and ultra-fast switching. Ideal for demanding test environments.

Key Features:

• Voltage range: 0–80 V DC
• Power scalable from 9 kW to 2000+ kW
• Modular: Up to 44 units (parallel, series, combined)
• Full sink/source mode with energy recovery
• Voltage rise/fall time <250 µs
• Current accuracy <0.02% FS
• Auto-ranging with a factor of 3
• Digital control: CV, CC, CP, CR, Ri-Sim
• User-friendly software and HMI options
• AnyWave + WaveMaster for waveform control
• CAN, API, and high-speed bus support

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 BAT EMC software suite by NEXIO is an advanced electromagnetic compatibility testing platform designed to automate, control, and streamline EMC testing workflows. Built for laboratories, automotive engineers, and compliance specialists, it enables accurate emission and immunity testing with powerful configuration and reporting tools.

Key Features

• Automated EMC emission and immunity testing workflows
• Supports conducted and radiated emission and immunity tests
• Configurable test parameters including RBW, detectors, scan time, and limits
• Automotive-focused testing aligned with CISPR25 standards
• BAT-ELEC module for transient, burst, and surge testing automation
• Real time monitoring tools including voltmeters, analyzers, and cameras
• Centralized project management for EMC test data and resources
• Multi brand compatibility for test generators and measurement equipment
• Automatic compliance report generation for regulatory requirements
• Designed for aerospace, automotive, healthcare, and industrial labs

The BAT metrology software suite by NEXIO is a precision-driven measurement solution designed to support EMC laboratories and engineering teams in analyzing, calibrating, and validating electrical and RF test systems. It enhances accuracy, ensures compliance, and simplifies complex measurement workflows across multiple testing environments.

Key Features

• Comprehensive metrology platform for EMC and RF measurement systems
• Supports VNA based testing for RSIL, RCD, and cable validation
• Oscilloscope based analysis for ESD guns and signal generators
• Amplifier calibration to maintain consistent performance standards
• BAT-NSA and SVSWR testing for anechoic chamber and OATS environments
• Ensures accurate signal measurement and system validation
• Improves compliance, reliability, and measurement consistency
• Suitable for EMC laboratories, research centers, and industrial testing
• Reduces calibration errors and improves test repeatability
• Supports modern metrology workflows for complex RF systems

The BAT-SCAN near field system is an advanced robotic EMC measurement solution designed to analyze and visualize electromagnetic behavior in electronic components and circuits. Developed by NEXIO, it enables precise near-field scanning to identify EMC issues early in the design stage, improving product reliability and reducing development costs.

Key Features

• Robotic near-field scanning system for EMC analysis
• High precision measurement accuracy up to 0.1 mm
• Measurement volume of 500 x 500 x 400 mm
• High speed scanning up to 1 m/s
• Integrated 4K high resolution camera for visual analysis
• Lightweight system design at 11.2 kg
• Automated EMC failure detection and localization
• Compatible with multiple robotic scanning platforms
• Supports PCB, IC, shielding, and enclosure analysis
• Reduces qualification test cycles and debugging time

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