Search Results

Sponsored Awards Sponsored Awards Home News & Articles Awards On several occasions in the past, Pro Digitek , jointly with BioLogic Science Instruments, have been the proud sponsors of awards presented at symposiums and conferences. These include poster sessions and awards in research excellence. We feel that these individuals deserve continued recognition for their innovation, enthusiasm and dedication with passion toward their field of study and also the support provided by their respective supervisors. This page is dedicated to these high achievers in their field of study. February 2020 ACES at Australian National University Proudly presented by Prof Gordon Wallace (University of Wollongong) Prof Maria Forsythe (Deakin University Vincent Stafrace (ProDigitek-Biologic) Posters: - 1st - Jawairia Umar Khan (UOW) - 2nd - Samuel Rathbone (UOW) - 3rd - Rebecca Hodgetts (Monash) Research Training Grants: - Student Research Training Grant - Sujani Abeywardena - ECR Research Training Grant - Dr Faezeh Makhlooghiazad February 2017 Prizes announced by Prof Gordon Wallace (University of Wollongong) Presented by Vincent Stafrace (ProDigitek Pty Limited) 1st Prize : Poster #5 Tom Barsby Neuron Ex Machina: In vitro Models of Neurological Development 2nd Prize: : Poster #79 Sara Zarghami Photo Controlled Micro Droplets 3rd Prize Poster #29 Shaun Geitmann Synthesis of Optically Active Drug Delivery System December 2016 Deakin University International Sodium Battery Symposium Awards Announced by Prof Maria Forsyth (Deakin University) Poster Awards: Presented by Vincent Stafrace (ProDigitek Pty Limited) Travel Awards: Presented by Dr William Eggers (Biologic USA) Student Travel Awards - James Christian Pramudita - Laurence Middlemiss - Hijiri Yamamoto - Shotaro Muratzubaki - Ronnie Mogensen - Jaione Martinez de Ilarduya - Imanol Landa-Medrano - Zhe Hu Best Poster Award - Ronnie Mogensen - Yusuke Yoda - Fangfang Chen - Laurence Middlemiss https://blogs.deakin.edu.au/aces-symposium/ Award Winners: Alexandr Simonov Best Showcase presentation Emma Sackville Student Poster Award Muataz Ali Student Poster Award Danah Al Masri Student Poster Award Medicinal Chemistry Catagory: Protein Resistance and Low Impedance Zwitterionic Phenyl Layers on Gold Electrodes for Electrochemical Biosensing Applications. Maryam Parviz - PhD Student - www.acn.unsw.edu.au - Supervisor - Scientia Professor J. Justin Gooding - School of Chemistry and Australian Centre for NanoMedicine - http://www.chemistry.unsw.edu.au/research/research-groups/gooding-group/group-members-current Ionic Liquids Catagory: Salt-on-a-Chip: Robust and Versatile "Wall-Less" Ionic Liquid Microreactors Achieved by Microcontact printing. Christian A Gunanwan - PhD candidate - Supervisor - A/Prof Chuan Zhao - School of Chemistry - http://newsroom.unsw.edu.au/news/science/new-lab-chip-device-overcomes-miniaturisation-problems 2014 August 24th XIV International Symposium on Polymer Electrolytes (ISPE14) Hosted by Deakin University. These students were presented with Travel Awards, to the Symposium, based on their research papers and their CVs. Mohd Sukor Su’Ait, Universiti Kebangsaan Malaysia, Malaysia Tian Khoon Lee, Universiti Kebangsaan Malaysia, Malaysia Nadhratun Naiim Mobarak, Universiti Kebangsaan Malaysia, Malaysia Siti Rudhziah Che Balian, University of Malaya, Malaysia Nurul Akmaliah Dzulkurnain, University of Malaya, Malaysia Salmiah Ibrahim, University of Malaya, Malaysia Nerea Casado, University of the Basque , Spain Guiomar Hernández, University of the Basque , Spain Anna Latoszynska, Warsaw University of Technology, Poland

The presence of other electrical equipment in the lab can affect your measurement, especially when measuring high impedance systems or very low currents. In this situation, electromagnetic noise emitted by external equipment can be picked up. To prevent this from happening a Faraday cage is needed. Home Products Electrochemistry Accessories E-Chem Faraday Cage Accessories Range Faraday Cage Keep artifacts away from your cell. The presence of other electrical equipment in the lab can affect your measurement, especially when measuring high impedance systems or very low currents. In this situation, electromagnetic noise emitted by external equipment can be picked up. To prevent this from happening a Faraday cage is needed. Request a quote Two Faraday cages are offered: a simple one and an advanced one. The advanced one offers additional gas flow control to maintain a certain type of environment in and above the electrolyte. Please remember that the Faraday cage needs to be earthed. It is usually done by connecting the outer shell of the cage to the earth (green receptacle at the back) of your instrument. It is also important to maintain the cell in the center of the cage. For this purpose, a rod is set by default and optional plate can be purchased. Further details are given below. Specifications and ordering information FC-45 Dimensions: 45 x 45 x 45 cm Material: stainless steel 430. Cable feed-through. A Feed-through (14 x 4 cm) is available on the left side. It is compatible with all Bio-Logic cables such as: Standard cable cable with electrometer i.e. Low Current, Ultra Low Current bipot cable for the VMP3 instruments booster cables eQCM cable Several cables can go through this feedthrough. Earth: connection: A 4-mm green plug is available on the rear panel to be connected to the Earth ground chassis of the instrument. Other input/output: On the rear panel, four openings are available to allow the user to connect the cell to any water or gas tubing. 2 holes (input/output) with a diameter of 2 cm for water tubing 2 holes (input/output) with a diameter of 1.5 cm for gas tubing A rod (diameter: 1.2 cm) is provided inside the cage. This can be used to fix the cell or the cell cable. Nut and clamp are not provided. A stand (PN: 094-084/2) is offered as option. It is made of two metallic plates of 20 x 20 cm separated by a plastic tube of 14.6 cm. This stand can be screwed to the Faraday cage. It is compatible with the coating, flat, galvanic cells.

Incorporates an extremely flexible sample accommodation platform, designed to take as wide a range of sample configurations as possible to meet the needs of the end user. The design of the Environmental TriCell™ system means it can be used with Scanning Kelvin Probe (SKP), Localized Electrochemical Impedance Spectroscopy (LEIS), Scanning Vibrating Electrode Technique (SVET), and Scanning Droplet Cell (SDC) measurements, on BioLogic’s modular M470 scanning electrochemical workstation. Home Products Electrochemistry SECM Accessories Environmental TriCell™ Cells Environmental TriCell™ Electrochemical cell to be used with SKP, LEIS, SVET and SDC Electrochemical cell to be used with SKP, LEIS, SVET and SDC Request a quote The Environmental TriCell™ incorporates an extremely flexible sample accommodation platform, designed to take as wide a range of sample configurations as possible to meet the needs of the end user. The design of the Environmental TriCell™ system means it can be used with Scanning Kelvin Probe (SKP), Localized Electrochemical Impedance Spectroscopy (LEIS), Scanning Vibrating Electrode Technique (SVET), and Scanning Droplet Cell (SDC) measurements, on BioLogic’s modular M470 scanning electrochemical workstation. The various configurations of the Environmental TriCell™ will allow users to change samples without moving the scanning head and reduce the volume of electrolyte required for scanning probe electrochemistry experiments. The base plate levelers incorporated into the design of the TriCell mean sample levelling can be performed to achieve the strongest signal throughout the scanning probe electrochemistry experiment. The clear glass body of the cell allows users to view the probe and sample with the VCAM3 long working distance video microscope system to aid in relative positioning during experiment setup. The Environmental TriCell™ system has four inlet/outlet purge ports and an optional rubber gaiter cover seal making it ideal for controlled atmosphere or liquid flow in scanning probe electrochemistry experiments. The Environmental TriCell™ is ideal for use in corrosion and coatings studies of various samples. Electrochemistry Accessories Catalog Environmental TriCell™ Specifications Triangular perspex base plate, 316 mm side length Base plate level adjusters, 33 mm extension range Glass cell, 143 x 60 mm, including gas and liquid ports; O-ring seal Cell clamp Sample holder for 32mm diameter metallurgical samples Flexible cell sealing gaiter PTFE sealing disk to allow use of organic electrolytes

Hexagon is a stand-alone, single or dual digital 32k MCA, integrating input stage for the signal conditioning, fast analog-to-digital converter (ADC), digital processing algorithms, HV and Preamplifier Power Supply in a compact desktop form factor. Home Products Nuclear Physics Equipment CAEN SyS Hexagon Product Overview Hexagon Digital Multi-Channel Analyzer. Single and Dual 32k Digital MCA & Pulse Processor Fully supported by Quantus High Performance Quantitative Spectrometry Software Provides Pulse Height Analysis (PHA with MSS and coinc/antocoinc), Time-stamped Lists and Multichannel Scaling (MCS) modes Ideally suited for high resolution spectroscopy applications utilizing HPGe, CZT, Silicon, and scintillation detectors such as NaI and LaBr3 Supports Resistive Feedback and Transistor Reset preamplifiers as well as PMT anode signals On-board SSD memory supports List and Spectrum data storage capability (up to 200,000+ spectra) Web interface for quick retrieval of board details, firmware upgrading, and output data file browsing Request a quote Hexagon is a stand-alone, single or dual digital 32k MCA, integrating input stage for the signal conditioning, fast analog-to-digital converter (ADC), digital processing algorithms, HV and Preamplifier Power Supply in a compact desktop form factor. Operating Modes Hexagon can be configured to operate in Pulse Height Analysis (PHA) acquisition mode, in Multichannel Scaling (MCS) acquisition mode, or in both PHA and MCS modes simultaneously. Multiple PHA spectra can be collected using Multispectral Scaling (MSS) mode with no data loss when switching to a new spectrum. The Time-Stamped List mode permits time and energy events to be saved either to on-board memory or to the host PC for offline analysis and post-processing. Analog input signals and internal digital filter outputs can be inspected via the Signal Inspector mode. Additionally, Compton/AntiCompton data acquisition is supported by taking advantage of the 2-input channel version. I/O Equipment and Additional Features Hexagon is equipped with I/O connectors which support several features beyond the standard MCA functionality. A DB25 I/O connector supports PHA Start/Stop, SCA, MCS, Coincidence/AntiCoincidence, Acquisition Start/Stop, ICR, Run Status, Sample Changer, and Sample Ready signals. The BNC connectors are reserved for Transistor Reset Preamp (TRP) inhibit, where the inhibit takes place on an external digital signal and can be extended in time via programming. Two SATA connectors allow for very precise multi-board synchronization, time stamp alignment, and system building via a simple daisy chain. Front Panel LED indicators inform the user as to board and I/O status, polarity of the power supply, and multi-board sync status. An OLED display provides general board information, real-time statistics on ICR, OCR, Real/Live/Dead Time, as well as details on the HVPS channel output. HV and LV Power Supply Hexagon can provide HV bias for up to two detectors. Three ranges of bias voltage and current, which are software configurable on a per-channel basis and hardware protected, allow the user to tailor the output V/I to specific detector types such as PMT (2 kV / 1 mA), HPGe (5 kV / 30 μA), and Silicon (500 V / 50 μA). The 2-input channel version of Hexagon allows the user to select the polarity configuration upon ordering: Positive-Positive, Negative-Negative, or Mixed. The 1-input channel version of Hexagon is provided with an HVPS configuration which includes 1-channel Positive Polarity and 1 -channel Negative Polarity. HV inhibit is supported with both positive and negative polarity. Hexagon also integrates low voltage outputs (±12 V / 100 mA and ±24 V / 50 mA) to power preamplifiers. Detector Temperature and Nitrogen Levels may be monitored via external sensor interface. Software Hexagon is controlled by Quantus , a general-purpose gamma-ray quantitative spectroscopy software. Independently of the detector geometry or sample used, Quantus can analyze any recorded gamma-ray spectrum for radionuclide identification and quantification. Multiple spectra can be analyzed at the same time, and/or acquiring data from several connected detectors is supported. The advanced Graphical User Interface incorporates tools for a wide set of necessary analysis functions: peak searching, peaks continuum subtraction, peak qualification, automatic ROI location, energy calibration with visual interaction, FWHM calibration, efficiency calibration, nuclide identification and activity calculation. Hexagon keeps the compatibility with MC2Analyzer (MC2A), CAEN multi-board configuration and data acquisition software with basical spectrum analysis (ROI, energy calibration, FWHM, statistics), supporting all CAEN MCAs and digitizers running the DPP-PHA algorithm. The embedded Linux-based ARM processor makes Hexagon well suited for unattended operations. Taking advantage of the available SDK tool, the user can customize the software (running embedded or on an external PC). The parameters of the processing algorithms can be tuned according to the detector or the application, and custom routines can be developed for automated operations, such as on-board spectrum and list recording, acquisition settings, logging and autonomous data acquisition when unconnected from external hosts. Connectivity Hexagon can be controlled with a point-to-point direct connection through the USB 2.0 link and with a remote network connection by the Ethernet 10/100T port. The module also features a web interface that supports basic operations (sans spectroscopy software) by simply opening a web browser. The web interface is a quick and useful tool for finding basic board information (e.g. model type, serial number, firmware version, CPU load averages, real memory occupancy), for retrieving files saved on the onboard memory, for setting operational functions for each run (e.g. order, cut, copy/paste files, create and delete directories, user rights, etc.), and for managing network settings and upgrading firmware. HEXAGON Product Presentation

In addition to high Current potentostats to 100A, Biologic offer a range of external and pluggable boosters for the entire range of potentiostats. Boosters Home Products Electrochemistry Boosters In addition to high Current potentostats to 100A, Biologic offer a range of external and pluggable boosters for the entire range of potentiostats. A range of Plug-in modules for both the traditional VSP and VMP Chassis (4 Amp Max) and SP-300, VSP-300 and VMP-300 up to 10 Amp. External Booster Chassis (8 slot) from 2 Amps to 20 Amps for the SP-150, VSP and VMP Chassis Newly released External +/-48V 30 Amp booster stackable to 120 Amp, the HCV-3048 is for the SP-200, SP-300, VSP-300 and VMP-300 seres Premium Boosters More info Premium Boosters More info Essential Boosters More info Essential Boosters More info HCV-3048 More info HCV-3048 More info FlexP0012 More info FlexP0012 More info FlexP0160 More info FlexP0160 More info

A research-grade multichannel potentiostat, the new VMP-3e’s modular design, makes it perfect for wide-ranging applications. However, the ability to connect each potentiostat to an external high-current booster channel makes it especially suitable for battery research / testing. Home Products Electrochemistry Potentiostats VMP3e Essential VMP-3e Power, performance and precision all rolled into one robust multichannel chassis. 16 channel electrochemical workstation with 1 A (extendable to 800 A) current capability as well as EIS Quality Indicators. Perfect for battery research & testing Request a quote A research-grade multichannel potentiostat, the new VMP-3e’s modular design, makes it perfect for wide-ranging applications. However, the ability to connect each potentiostat to an external high-current booster channel makes it especially suitable for battery research / testing. A standard voltage range of ±10 V is extendable to -20 V to +20 V. And the standard current of ± 1 A can be brought down to 20nA – via modules that can be easily added in-situ, by the user, enabling the instrument to grow with your needs. For high-end EIS measurements, a 1 MHz specification is complemented by BioLogic Quality Indicators, a feature previously only available on BioLogic Premium instruments. Quality Indicators enable scientists to quickly and efficiently validate their impedance measurements. Only BioLogic offers three Quality Indicators, making this the most comprehensive range available. Additional features include CE to GND mode, unique to BioLogic, which enables users to choose from independent channel or multi-electrode configurations and LAN connectivity to improve multi-user working. Powered by EC-Lab® , the advanced, ergonomic software that has earned itself the reputation as a global benchmark for potentiostat control software, the VMP-3e boasts a vast array of unique functionality. Only EC-Lab enables users to build and modify experiments incrementally with “modify-on-the-fly”. But a vast array of presets is available, if necessary. The VMP-3e is a true benchmark electrochemical workstation. A multichannel potentiostat which, when combined with the power of BioLogic’s EC-Lab® instrument control and data analysis software, will help take your research to the next level. VMP-3e Specifications Voltage Control voltage: ±10 V adjustable between[-20; to +20] V (standard); up to 60 V with FlexP0060/FlexP0160 Voltage resolution: 5 µV on 200 mV range Compliance: ±10 V adjustable between [-20; to +20] V (standard) Current 1A with “e” type board (400mA with standard board) down to 10µA (1nA with low current option) Maximum current: ±1 A (continuous); up to 800 A with four FlexP0012 Current resolution: 0.760 nA; down to 76 fA (Low Current) EIS Frequency range: 1 MHz down to 10 µHz EIS Quality Indicators (with “e” type board) Advanced Up to 16 channels Connection 2,3,4,5 terminal lead Best acquisition time: 200 µs Stability control mode (7 bandwidths) VMP-3e Electrochemisty Instrument Catalog

Accessory to enable the conversion of stopped flow/chemical flow to a freeze quench in minute. Freeze quench can be used to study full and intermediate kinetics by trapping reaction intermediates, whose presence has been determined by stopped-flow experiments. Home Products Kinetics and Spectroscopy Freeze quench Product Overview Freeze quench Accessory to enable the conversion of stopped flow/chemical flow to a freeze quench in minute. Freeze quench can be used to study full and intermediate kinetics by trapping reaction intermediates, whose presence has been determined by stopped-flow experiments. Request a quote When chemical quenching is not suitable for a rapid kinetics study, fast freezing the reaction to quench it may be the best option. Freeze quench experiments are divided into three phases: mixing, ageing and freezing. The frozen reaction products are collected and analyzed by EPR/NMR, Mossbauer or XAFS in their solid state. Freeze quench can be used to study full and intermediate kinetics by trapping reaction intermediates, whose presence has been determined by stopped-flow experiments. Freeze quench techniques are also extensively used to study metallic reaction centers in metalloproteins and metalloenzymes. Freeze quench experiments are made possible thanks to the coupling of one premium SFM stopped-flow with the freeze quench accessory. Freezing is carried out by ejection into a -130°C isopentane bath cooled down by liquid N2 circulation. To limit the number of steps required during the packing process and to avoid the risk of warming up the frozen solution, aged solution is ejected directly into a cooled Teflon funnel. The sample holder is attached to the bottom of the funnel cone so the sample can be packed easily with the packing rod (included). Holders are available to collect samples for spectroscopic analysis by EPR/NMR, Mossbauer, and XAFS. 9 ms ageing total time can be achieved in freeze quench mode. The Freeze quench set-up can be converted to a stopped-flow or chemical quench in minutes. SFM Series brochure

Leading Supplier of Scientific & Analytical Equipment for the Electrochemical & Renewable Energy Industries with over 24 years of experience About us Leading Supplier of Scientific & Analytical Equipment for the Electrochemical & Renewable Energy Industries with over 24 years of experience . Cutting-edge hardware. Powerful, user-friendly software. The quality, reliability, and innovation that lies behind Prodigitek’s product portfolio help shape the future of research/industry projects around the world. Our close professional proximity with both academic and industrial users helps us understand our clients’ needs and develop solutions that truly make a difference – through a marriage of cutting-edge, reliable, high-performance hardware and innovative, user-friendly software. The Directors Foreword. Shaping the future. Together. Whilst my background is Electronic Engineering, it appears that my career was destined to be one involving Potentiostats and becoming involved in the science of Electrochemistry and more recent years Nuclear Physics. From repairing Potentiostats back in the mid 70’s, Sales and Support in the late 80’s and then establishing ProDigital in 1996. The Electrochemistry industry had grown so much, that in 2004, I established ProDigitek to exclusively focus on the Scientific Instruments Sector and specializing in niche measurement systems for Electrochemical applications. Originally PAR, Solartron and Biologic, it was Biologic that ultimately became the star. In more recent years another division, CAEN instruments who are the Biologic equivalent in Nuclear Physics instrumentation. I never realised that the combination of Electronic Engineering skills and the passion for science would be such a remarkable combination. Over 36 years, I was absorbed in the world of Electrochemistry and became fascinated by the Science and those that used our Instruments. In the early days circa 1988 when PC’s and software started to take over “manually used” Potentiostats with XY recorders and attended my first ACA Conference, researchers knew their science but PC’s and software were a bit of a mystery for many. That’s were I came in and started to train researchers in how to operate our software to obtain the data they needed to analyse. Today of course, most everyone is familiar with PC’s and Software In the meantime, and over the years, I had not only attended several conferences, seminars, training sessions and been exposed to real applications, learning about real objectives and how to achieve them, but also became proficient in trouble shooting common problems that occur in setting up experiments and the software that run our Biologic Potentiostats. Today I find myself enjoying the people I meet and the many friends I have made in the industry. Some are considered Demi Gods in their respective discipline by very young students today. It is how one realises that they are getting older. It has been most gratifying to see that all the knowledge I had acquired became useful and to be able to support and participate in the discipline of this Science. Not only to see how the present has been shaped from the past, but also how the combination of the collective skills can shape the future. Of course, it’s not just the knowledge acquired over the years that is here to support you, but I am also backed up some 15+ PhD’s employed by Biologic and about the same in CAEN. Today I find myself joyfully waking up looking for emails from those that need assistance. I believe, that unknowingly, the passion to be indefinitely helpful and supportive to our customers that was there since the day I was born, has shaped my path in life and continues to drive me to this very day. This is something I am passing onto our team here at ProDigitek. Please know that our Philosophy at ProDigitek is that we do NOT take your money and run. No matter what you purchase from us, you have a partner in your research and objectives that wants you and will do anything for you to SUCCEED. Vincent Stafrace Managing Director/Owner of Prodigitek

The MPG-200 series is a high-end battery tester series made of two core configurations. The MPG-2 features 16 independent channels at 100 mA, whereas the MPG-205 offers eight 5 A channels. Both MPG battery cyclers are available with or without EIS capabilities. Home Products Battery Cyclers MPG-200 Request a quote Research Grade MPG-200 series The MPG series: Precision, stability and power – perfect for in-house R&D or academia. The MPG-200 series is a high-end battery tester series made of two core configurations. The MPG-2 features 16 independent channels at 100 mA, whereas the MPG-205 offers eight 5 A channels. Both MPG battery cyclers are available with or without EIS capabilities. The power of a high-end potentiostat/galvanostat, the simplicity of a battery cycler. MPG-200 series battery cyclers’ high-end specification has been designed to address the most demanding battery testing needs possible. Equipped with five leads to connect to batteries with reference electrodes, the MPG-2 features 16 channels with a maximum current of +- 100 mA per channel, its voltage range of +- 10 V makes it suitable for any cell (half, full, symmetrical) configuration. The MPG-205 features 8 channels at ± 5A. With its voltage range from -2 to + 9 V, this cycler has four electrode connections. Both units share a 200 µs time-base/sampling rate, a remarkable 800 pA current resolution, and their dynamic range can lower their voltage resolution down to 5 µV. Electrochemical Impedance Spectroscopy (EIS) is available as an option and can run simultaneously on every channel from 20 kHz to 10 µHz. Each channel can be equipped with a Pt-100 probe for temperature measurements and can interface external devices through analog and digital input/output. Both units can be stacked in a five-position rack, giving users total autonomy to develop a bespoke system to perfectly fit their needs. Perfectly suited for energy applications MPG-200 series instruments feature a comprehensive set of battery-specific and general electrochemistry techniques and analysis tools including: • PITT • GITT • Linear Sweep Voltammetry • Chronoamperometry • Chronopotentiometry • Differential Coulometry (dQ/dV) • High Precision Coulometry (HPC) • Electrochemical Impedance Spectroscopy (EIS) • Capacity slippage • User profile • Pulse techniques MPG-200 Series Brochure MPG Series Specifications

Built around a 5-channel modular chassis the VSP is a versatile, research-grade potentiostat. Home Products Electrochemistry Potentiostats VSP Essential VSP 5 channels - A versatile, research grade, multichannel instrument EIS measurement from 10 µHz to 1 MHz, Current ranging from 10 μA up to 1 A Request a quote Built around a 5-channel modular chassis the VSP is a versatile, research-grade potentiostat. This highly modular electrochemical-workstation can reply to the needs of all scientists with options for EIS capability, low current, high current booster and additional potentiostat channels. The internal 4 A option takes two slots in the VSP chassis and requires a potentiostat board. External boosters from 2 A up to 100 A can be used with each channel in the VSP. VSP Specifications Voltage Control voltage: ±10 V adjustable between[-20; to +20] V (standard); up to 60 V with FlexP0060/FlexP0160 Voltage resolution: 5 µV on 200 mV range Compliance: ±10 V adjustable between [-20; to +20] V (standard) Current Current ranges: 400 mA to 10 µA (standard); down to 1 nA (Low Current) Maximum current: ±400 mA; up to 800 A with four FlexP0012 Current resolution: 0.760 nA; down to 76 fA (Low Current) EIS Frequency range: 1 MHz down to 10 µHz Advanced Up to 5 channels Connection 2,3,4,5 terminal lead Best acquisition time: 20 µs with EC-Lab Express; Stability control mode (7 bandwidths) VSP Brochure Electrochemisty Instrument Catalog

As a leader in this field, BioLogic has over 30 years of experience of developing equipment designed to give researchers a cutting-edge. Originally dedicated to rapid kinetics measurements, BioLogic now also develops, integrates and manufactures a wide range of instrumentation for steady-state spectroscopy including spectropolarimeters. Home Products Active Technologies Arbitrary Waveform Generators AWG-4000 Waveform Generator Range ARB RIDER AWG-4000 ARBITRARY WAVEFORM GENERATOR 2, 4 and 8 Channel Arbitrary Waveform Generator The ARB Rider AWG-4000 series is a powerful set of 2, 4 and 8 channel Arbitrary Function Generators (AFG) and Arbitrary Waveform Generators (AWG) from Active Technologies. AWG-4000 offers up to 1 GHz bandwidth, up to 24Vpp output range and up to 1024 Msample memory depth, making this family the ideal choice for Automotive, Aerospace & Defense, Big Physics and Semiconductor Test applications. Up to 8 analog channels per unit and up to 32 digital lines (TTL or LVDS standards) allows the user to create a mixed signal generation setup to generate analog and digital stimuli. AWG-4000 is the ideal choice as multi channel Arbitrary Waveform Generator. Models Get a Quote AWG-4018: 1.2 GS/S | 16 BITS | 8 CHANNELS ARBITRARY WAVEFORM GENERATOR 7" Capacitive Touch Screen Display Soft Keyboard 8 BNC Analog Outputs 4 BNC Marker Outputs and 1 Trigger Input 4-IN-1 Instrument The AWG-4000 Series instruments are multifunctional signal generator s that combine four functions in one instrument, including Function Generator, Arbitrary Waveform Generator, Digital Pattern Generator and Serial Data Pattern Generator . These four-different functionalities expand the HW flexibility adopting two different technologies: Improved DDS in AFG mode and variable clock, true-arbitrary technology in AWG mode. The AFG mode allows the user to change glitch free on-the-fly all the parameters preserving the waveform shape and to create/generate the waveform in a glace. The AWG mode lets the user create complex wavefevorm of analog and digital patterns, insert them in a sequence, apply loops, jumps and conditional branches. The Serial Data Pattern mode is designed to generate a stream of binary information. With up to 8 channels of data stream, built-in PRBS sequences, modulation features, transition shaping, and the flexibility of a powerful analog front-end, the SPG is the perfect tool for the most challenging applications. Highlights Up to 1024 Mpoints of waveform memory on each channel 16384 sequencer entries Analog and Digital signals fully synchronized Serial Data Patterns Generation Aerospace & Defence Electronics warfare signals driven by Radar or Sonar systems perfectly match with AWG-4000 Series generators. The AWG-4000 Series AWGs can be used on digital modulation systems for Radio Applications or others I/Q signal modulation. Moreover pulses can be easily generated for applications such as Pulse Electron Beam or X Ray Sources, Flash X-ray Radiography, Lighting pulse simulators, high Power Microwave modulators. Highlights Generate Radar test signals with excellent spurious performance Create Electronic Warfare complex scenarios with up to 16384 sequencer entries and Advanced Sequencer conditional/unconditional jumps. Up to 12Vpp into 50 Ohm Pulse Amplitude with ± 2.5V hardware offset Fast Rise Time Pulses: up to 900 ps rise/fall time Automotive, IoT and Ind. 4.0 Today’s cars are including lots of highly sophisticated electronic control units (ECU) with very sensitive electronic components. The 16-bits vertical resolution combined with High-Sampling Rate and 12Vpp (24 Vpp on High Impedance Load) output amplitude range, make the AWG-4000 Series instruments indispensable tools for successfully addressing the new testing challenges in automotive. Wireless technologies are driving the next industrial revolution, taking productivity and efficiency to new levels. Manufacturing is becoming more intelligent, flexible and dynamic. As result, wireless connectivity is becoming even more business and mission critical, leading to very strict requirements with respect to reliability, latency and security. Following those scenarios, the AWG-4000 Series Waveform Generators gives you the possibility to emulate complex RF I/Q modulation for simulation and Test on wireless devices or working on Internet of things of industry 4.0 applications. Highlights CAN, CAN-FD, LIN, Flexray, SENT emulation and troubleshooting 100BASE-T1, 1000BASE-T1, BroadR-Reach emulation and immunity from interference signal and noise Power Integrity testing of electric and electronic components for use in motor vehicles at low voltage Sensors signals generation: emulation of ideal signals or generation of real world signals after acquisition with an High Definition Oscilloscope . MOSFET gate drive amplitude signal emulation for MOSFET characterization and optimization Electrical standards emulation up to 24 V MEMS sensor testing : up to 24 V – 2.5ns rise and fall time Multi-Instrument Synchronization You can synchronize up to 4 units to build a system made of 32 analog channels and 128 digital channels fully synchronized and integrated with the True-Arb software. Main Features Synchronize up to 4 units: 32 Analog channels and 128 Digital channels Easy to use Multi-Instrument control through True-Arb software Address modern applications that require an high number of channels Quantum Computing Systems with Multiple Qubits Technical Specifications 1.2 GS/s, 16 Bit Vertical Resolution Minimum Edge time down to 1.1 ns Maximum dynamic range up to 12Vpp into 50 ohms Up to 1024 Mpts per Channel 8 Digital Channels in synchronous with analog Generation SW User Interfaces: Expert Rider for AWG mode and Simple Rider for AFG mode Semiconductors Test and Research Centers Researches require to emulate signals adding amplitude and timing variation imperfections in an accurate, detailed and repeatable controlled manner. Physics, electronics, chemistry, mechanics and other disciplines can benefit from the super intuitive user interface and from the hardware flexibility. The most challenging setup for your tests can be addressed in few minutes. Today’s IC, components, electronic circuits and sensors are required to be highly reliable extending the operating range in many variables. Emulation of complex signals generated with inclusion of noise or distortions may became an excellent way to provide Compliance Components Test to help semiconductors engineers. Highlights Clock generation for component overclock behavior and operating range limit and stress test Power up sequences of IC using the low impedance feature (5 Ω output impedance) Emulation of signal sources adding noise and known modulation distortion Quantum Computing Modulating and driving laser diode with detailed waveform generation Generation/playback of real-world signals previously acquired using an Oscilloscope and imported into the AWG-4000 Series generator Double pulse test setup in few seconds to measure switching parameters and evaluate the dynamic behaviors of MOSFET and IGBT power devices Emulation of long PRBS sequences with the SPG option Generation of multi-level and multi-edge pulses long waveforms with the SPG option Test With Confidence Software User Interface Key Features Download Documents Superior Testing Touch Gesture 7″ Touch Screen display and Soft Keyboard Digital Analog Channel + 32 Digital Channels Trigger, View, Generate and Sync AFG and DPG all in One Instrument Easily Create Waveforms and Pulses with Simple Rider UI Get a Quote

Active Technologies manufactures the industry’s best signal stimulus solution as fast pulse generators, arbitrary waveform generators and data pattern generators. Active Technologies Home Products Active Technologies Waveform Generator Range Signal Generators Arbitrary Waveform Generator (AWG) & Pulse Pattern Generator (PPG) 2, 4 and 8 Channel Arbitrary Waveform Generator and Pulse Pattern Generator solutions are ideal choice in automated test benches, for physics experiments, semiconductor tests, analog and digital debugging. Multiple units can be synchronized to build: 8 channel 16 channel 32 channel arbitrary waveform generator and / or Pulse Pattern Generator sources. Arbitrary Waveform Generators More info Arbitrary Waveform Generators More info Pulse Generators More info Pulse Generators More info NI FlexRIO Adapter Modules More info NI FlexRIO Adapter Modules More info Such kinds of equipment may generate stimulus to test devices like amplifiers, RF receivers, serial and parallel buses. In the case an engineer needs to characterize a new device, but the complete system is not available for the test, a signal generator can emulate the presence of the real system. Let’s assume an electronic engineer is going to develop a new sensor amplifier for a large physic experiment (i.e sensor amplifier for particle accelerator ). Once the amplifier protoye is ready, the engineer cannot test it connecting the accelerator as a source, because it means stop the experiment. In such case and Arbitrary Waveform Generator or a Pulse Pattern Generator can be used to emulate the accelerator sensor signals. In addition Active Technologies Arbitrary Waveform Generators can be used also as Pulse Generator s delivering fast rise time, adjustable amplitude and programmable offset. Most common applications are in the field of nuclear Physics, Defence Electronics and Radar emulation. Signal Generators – Key Features Arbitray Waveform Generators (AWG) and Pulse Pattern Generators (PPG) Generate Analog and Digital signals Create and reproduce Real-World signals Advanceded Research, Quantum Computing, RF and Wireless signals, Aerospace & Defense, Automotive, Educational and many more applications Multi-Instrument synchronization to increase the number of channels Easy to use software Interface Waveform Generator Range Pattern Generators The Digital Pattern Generator product family: DPG The DPG option allows you to create digital stimuli synchronous with analog channels to test and debug Mixed-Signal applications: they can be used for FPGA / peripheral / ASIC emulation and stimulation, protocol level testing setup/hold verification, production test, mixed signal testing and general digital stimulus.Up to 32 digital channel @ 1.2 GSps per instruments support different electrical standards like LVDS or LV-TTL. The Pulse Pattern Generator product family: PPG The Pulse Pattern Generator family is designed to generate a stream of binary information. The binary data stream is generated through the front panel BNC/SMA connectors. With up to 8 channels of data stream, built-in PRBS sequences, modulation features, transition shaping and the flexibility of a powerful analog front end, the SPG is the perfect tool to address the most challenging application where the digital data should be modelled with analog characteristics. It is a T&M instrument able to generate signals that allows testing electronic devices. They are the ideal tools for device characterization, compliance and measurements tests and real world signal replication. What are the different categories of signal generators? There are three main signal generator categories: Arbitrary Function Generators, Arbitrary Waveform Generators and Pulse Pattern Generators . What is the best signal generator? It depends on the application that you need to test. Typically Arbitrary Function Generators offers simplicity and fast setup time, but limited performance, while Arbitrary Waveform Generators offer more powerful performance but they take more time to be programmed. Finally Pulse Pattern Generators are designed to generate digital patterns and emulate communication protocols or test electronic components. What is the difference between arbitrary waveform and function generator? The Arbitrary Waveform Generators are sophisticated playback systems that creates signals based on stored digitala data. The AWG’s ability is to create virtually any type of waveform with high precision and accuracy. The Arbitrary Function Generator is based on DDS (Direct Digital Synthesis) technique and it produces the most common test signals used in laboratories and design departments. The AFG Function Generator delivers excellent frequency agility and modulation. What is a signal generator used for? The signal generators are used to test electronic devices and systems. They are the reference instrumentation family for applications that require the reproduction of real life signals such as Quantum Computing, RF and Wireless applications, IQ modulation, radar and lidar testing, semiconductor test, advance research in electronic, chemistry and physics, aerospace and defense applications. What are the types of signal generators? They are: AFG Arbitrary Function Generators, AWG Arbitrary Waveform Generators , DPG Digital Pattern Generators, SPG Serial Data Pattern Generators, Pulse Generators and Pulse Pattern Generators . What does a signal generator do? AWG-5000: WORLD’S FASTEST 16 BITS WAVEFORM GENERATOR 6.16 GS/S – 16 BITS – 5VPP OUTPUT VOLTAGE AWG New RF Mode: 12.32 GS/s sample rate / 6 GHz bandwidth More Info