Name: Model 685C Arbitrary Waveform Generator
Brand: Berkeley Nucleonics

1Overview

The Berkeley Nucleonics Model 685C is a high-performance arbitrary waveform generator built for laboratories and production lines that need both speed and signal fidelity from one instrument. Sample rate can be programmed from 1 S/s to 3 GS/s, with 16-bit vertical resolution throughout, ensuring exceptional signal integrity. Rise and fall time is 320 ps.

The platform scales with the channel count. It is available with 2, 4, or 8 analog channels, each backed by deep arbitrary waveform memory of up to 4 Gpts per channel. Optional digital channels, up to 32 in total, run in synchronous with analog generation, so a single unit can drive both the analog and digital sides of a mixed-signal design.

Two operating modes cover the span of waveform work. Simple Rider AFG provides a direct digital synthesis function generator, and Simple Rider True Arb gives variable-clock arbitrary generation with synchronized digital pattern output in DPG mode. A 7-inch capacitive touchscreen, front-panel buttons, and a control knob make local operation fast, while LAN, USB-TMC, and GPIB support full remote automation.

Model 685C front panel with touchscreen and channel outputs — Model 685C front panel: 7-inch capacitive touchscreen, control knob, numeric keypad, and SMA channel, marker, and trigger connectors.

2Key Features

High sample rate, high resolution. Programmable from 1 S/s to 3 GS/s, with 16-bit vertical resolution for exceptional signal integrity.
Deep waveform memory. Arbitrary waveform memory up to 4 Gpts for each analog channel.
Mixed-signal generation. 2, 4, or 8 analog channels with 8, 16, or 32 synchronized digital channels for debugging and validating digital designs.
Two operating modes. Simple Rider AFG (DDS function generator) and Simple Rider True Arb (variable-clock arbitrary generation with DPG digital pattern output).
Fast edges. 320 ps rise and fall time for clean pulse generation.
High-rate digital outputs. Up to 750 Mb/s data rate in LVDS format, with an optional LVDS to LVTTL adapter.
Advanced sequencer. Up to 16,384 user-defined waveforms for complex signal scenarios with efficient memory use.
Multi-unit synchronization. Up to 4 instruments combine into a 32 analog, 128 digital channel generator over a dedicated synchronization bus.
Built for the bench and the rack. Compact Windows-based platform that fits a 3U 19-inch rack-mount standard, with LAN, USB-TMC, and GPIB control.

3Model Selection

The Model 685C is configured by analog channel count. Analog outputs are differential, DC coupled in every configuration. Optional digital channels add synchronized digital pattern outputs alongside the analog channels.

Model	Analog channels	Digital out (optional)	Marker out	Output type
Model 685C-2C	2	0 / 8	1	Differential, DC coupled
Model 685C-4C	4	0 / 8 / 16	2	Differential, DC coupled
Model 685C-8C	8	0 / 8 / 16 / 24 / 32	4	Differential, DC coupled

4User Interface

Simple Rider AFG: Function Generator Mode

The Simple Rider AFG user interface is designed using a touchscreen interface; it has been developed to put all the capabilities of modern waveform generators right at your fingertips. All instrument controls and parameters are accessible through an intuitive UI that recalls the simplicity of modern tablets and smartphones. Swipe gestures give easy access to the output waveform parameters, a touch-friendly virtual numeric keypad improves data entry, and time-saving shortcuts and intuitive icons simplify instrument setup.

Simple Rider AFG function generator touchscreen interface — Simple Rider AFG: direct digital synthesis function generator mode.

Simple Rider True Arb: AWG and DPG Mode

In the Simple Rider True Arb interface, users can define complex waveforms with up to 16,384 sequence entries of analog waveforms and digital patterns, and define their execution flow by means of loops, jumps, and conditional branches. Digital output combined and synchronized with analog output signals is an ideal tool to troubleshoot and validate digital designs.

Simple Rider True Arb arbitrary waveform sequencer interface — Simple Rider True Arb: variable-clock arbitrary waveform and sequence editor.

Simple Rider DPG digital pattern interface — Simple Rider DPG: digital pattern generation synchronized with analog output.

The waveform memory length of up to 4 GSamples per channel, combined with up to 16,384 sequence entries and up to 4,294,967,294 repetitions, makes the Model 685C suited to the most demanding technical applications. Up to 4 instruments can be synchronized together to obtain a 32 analog, 128 digital channel generator, and a dedicated synchronization bus guarantees intra-chassis synchronization. The Model 685C supports the standard Ethernet interface for remote control and easy customized instrument programming.

5General Specifications

All specifications are typical unless noted otherwise. The guaranteed performances are referred to a calibrated instrument that has been stored for a minimum of 2 hours within the operating temperature range of 5 C to 40 C and after a 45-minute warm-up period, within plus or minus 10 C after auto-calibration.

Operating modes: AFG Mode and True Arb Mode. The Model 685C is available as the 685C-2C, 685C-4C, and 685C-8C.

Output Channels

Parameter	Specification
Output type	Differential DC coupled
Output impedance	Single ended: 50 ohms; Differential: 100 ohms
Connectors	SMA on front panel

DC Amplitude

Parameter	Specification
Amplitude range	Plus or minus 0.75 V Se. (into 50 ohms); plus or minus 1.5 V Diff. (into 100 ohms)
Resolution	100 uV (nominal), 5 digits
Amplitude accuracy (guaranteed)	Plus or minus (1% of \|setting\| + 2 mV)¹

DC Baseline Hardware Offset (Common Mode Offset)

Parameter	Specification
Resolution	Less than 4 mV or 4 digits
Range (50 ohms into 50 ohms)	-2 V to +2 V
Range (50 ohms into high-Z load)	-4 V to +4 V
Accuracy (50 ohms into 50 ohms, guaranteed)	Plus or minus (1% of \|setting\| + 5 mV)
AC accuracy (1 kHz sine, 0 V offset, >5 mVp-p, 50 ohm load, guaranteed)	Plus or minus (1% of setting [Vpp] + 5 mV)¹

¹ The specification is guaranteed in the range 0% to 90% of full scale output.

6True Arb, Baseband Mode

Parameter	Specification
Operating mode	Variable clock (True Arbitrary), baseband mode
Sample rate	1 S/s to 3 GS/s
Sin(x)/x	1.32 GHz at 3 GS/s
Run modes	Continuous, Triggered Continuous, Single/Burst, Stepped, Advanced
Vertical resolution	16 bit
Waveform length	2G samples per channel (up to 4G samples optional)
Waveform granularity	1 if the entry length is > 416 samples; 32 if entry length is between 128 and 416 samples
Sequence length	1 to 16,384
Sequence repeat counter	1 to 4,294,967,294 or infinite
Timer range / resolution	20 ns to 1.39 s; plus or minus 1 sampling clock cycle
Analog channel-to-channel skew range	0 to 2.63 us
Skew resolution	100 fs
Skew accuracy	Plus or minus (1% of setting + 20 ps)
Initial skew	Less than 20 ps

Dynamic Performance

Parameter	Specification
Calculated bandwidth (0.35 / rise or fall time)	Greater than or equal to 1.1 GHz
SFDR at 100 MHz (Fsa = 6 GS/s, measured across DC to Fs/2, excluding fsa - 2×fout and fsa - 3×fout and excluding harmonic)	Less than -90 dBc
SFDR (Fsa = 6,16 GS/s, measured across DC to Fs/2, excluding fsa - 2×fout and fsa - 3×fout and excluding harmonic)¹	1 uHz to < 100 MHz: < -90 dBc 100 MHz to ≤ 600 MHz: < -82 dBc 600 MHz to ≤ 1.5 GHz: < -75 dBc 1.5 GHz to ≤ 2 GHz: < -70 dBc 2 GHz to ≤ 3 GHz: < -62 dBc
Rise/fall time (1 Vp-p single ended, 10% to 90%)	Less than or equal to 320 ps
Rise/fall time (1 Vp-p single ended, 20% to 80%)	Less than or equal to 200 ps
Overshoot (1 Vp-p single ended)	Less than 6%
Random jitter on clock pattern (rms, typical)	Less than 2 ps

¹ Reproduced verbatim from the source data sheet. The SFDR sampling-rate notations (Fsa = 6 GS/s and Fsa = 6,16 GS/s) appear as printed in the published Model 685C data sheet.

7AFG Mode

Parameter	Specification
Amplitude	0 to 3 Vpp Diff. (into 100 ohms); 0 to 1.5 Vpp Se. (into 50 ohms)
Resolution	100 uV (nominal), 5 digits
Operating mode	DDS mode
Standard waveforms	Sine, Square, Pulse, Ramp, more (Noise, DC, Sin(x)/x, Gaussian, Lorentz, Exponential Rise, Exponential Decay, Haversine)
Run modes	Continuous, modulation, sweep, burst
Arbitrary waveforms	Vertical resolution 16-bit; waveform length 16,384 points
Internal trigger timer	Range 10.4 ns to 88 s; resolution 80 ps; accuracy plus or minus (0.1% setting + 5 ps)

Sine Waves

Parameter	Specification
Frequency range Sine (50 ohms into 50 ohms)²	1 uHz to ≤ 1 GHz: 3 Vpp Diff.; 1 uHz to ≤ 1 GHz: 1.5 Vpp Se.
Flatness	DC to 2 GHz: plus or minus 0.5 dB (1 Vpp diff., relative to 1 kHz)
Spurious (measured across DC to Fs/2)³	1 uHz to ≤ 250 MHz: < -85 dBc 250 MHz to ≤ 500 MHz: < -80 dBc 500 MHz to ≤ 1.5 GHz: < -70 dBc 1.5 GHz to ≤ 2 GHz: < -60 dBc
Phase noise (1 Vp-p, 10 kHz offset)	20 MHz: < -127 dBc/Hz typ.; 100 MHz: < -123 dBc/Hz typ.; 1 GHz: < -105 dBc/Hz typ.

² Amplitude doubles on HiZ load. ³ SFDR is evaluated at 1 Vpp differential nominal output amplitude provided to the spectrum analyzer through a Mini-Circuits TC1-1-13M+ balun.

Square, Pulse, and Other Waves

Parameter	Specification
Square wave frequency range	1 uHz to ≤ 385 MHz
Square rise/fall time	800 ps (10% to 90%); 600 ps (20% to 80%)
Square overshoot / jitter	Less than 2%; less than 2 ps rms
Pulse frequency range	1 uHz to ≤ 385 MHz
Pulse width	1 ns to (Period - 1 ns)⁴
Pulse width resolution	20 ps or 15 digits
Pulse duty	0.1% to 99.9% (limitations of pulse width apply)
Leading/trailing edge transition time	800 ps to 1000 s (10% to 90%); 600 ps to 1000 s (20% to 80%)
Transition time resolution	2 ps or 15 digits
Pulse overshoot / jitter	Less than 2%; less than 2 ps rms (with rise and fall time ≥ 400 ps)
Double pulse frequency range	1 uHz to ≤ 192.5 MHz: 6 Vpp Diff.; 1 uHz to ≤ 192.5 MHz: 3 Vpp Se. (other pulse parameters same as Pulse Waves)
Ramp frequency range / linearity / symmetry	1 uHz to 37.5 MHz; linearity less than or equal to 0.1% (< 10 kHz, 1 Vp-p, 100%); symmetry 0% to 100%
Other waves (Exp. Rise/Decay, Gaussian, Lorentz, Haversine)	1 uHz to 37.5 MHz
Sin(x)/x frequency range	1 uHz to 75 MHz
Additive noise bandwidth (-3 dB) / level	2 GHz; 0 V to 0.75 V single ended and 0 V to 1.5 V differential, minus abs(carrier max value [Vpk]); resolution 1 mV
Arbitrary number of samples	2 to 16,384
Arbitrary frequency range	1 uHz to ≤ 385 MHz
Arbitrary analog bandwidth (-3 dB)	470 MHz
Arbitrary rise/fall time / jitter	800 ps (10% to 90%); 600 ps (20% to 80%); less than 2 ps rms
Frequency resolution	Sine, Square, Pulse, Arbitrary, Sin(x)/x: 1 uHz or 15 digits; Gaussian, Lorentz, Exp. Rise/Decay, Haversine: 1 uHz or 14 digits
Frequency accuracy (Non-ARB)	Plus or minus 2.0 ppm of setting; plus or minus 500 ppb of setting optional
Frequency accuracy (ARB)	Plus or minus 2.0 ppm of setting plus or minus 1 uHz; plus or minus 500 ppb of setting plus or minus 1 uHz optional

⁴ Below 1 ns width, the pulse amplitude will have some reduction with respect to the set value.

8Modulation & Sweep

The Model 685C supports AM, FM, PM, FSK, PSK, and PWM, plus linear, logarithmic, staircase, and user-defined sweeps. Modulation sources can be internal or external.

Function	Specification
Amplitude Modulation (AM)	Carrier: standard waveforms (except Pulse, DC, Noise), ARB; source internal or external; modulating waveforms Sine, Square, Ramp, Noise, ARB; modulating frequency internal 500 uHz to 61 MHz, external 10 MHz max; depth 0.00% to 120.00%
Frequency Modulation (FM)	Carrier: standard waveforms (except Pulse, DC, Noise), ARB; source internal or external; modulating waveforms Sine, Square, Ramp, Noise, ARB; modulating frequency internal 500 uHz to 61 MHz, external 10 MHz max; peak deviation DC to 1 GHz
Phase Modulation (PM)	Carrier: standard waveforms (except Pulse, DC, Noise), ARB; source internal or external; modulating waveforms Sine, Square, Ramp, Noise, ARB; modulating frequency internal 500 uHz to 61 MHz, external 10 MHz max; phase deviation range 0 to 360 degrees
Frequency Shift Keying (FSK)	Carrier: standard waveforms (except Pulse, DC, Noise), ARB; source internal or external; modulating waveform Square; key rate internal 500 uHz to 61 MHz, external 10 MHz max; hop frequency DC to 1 GHz; 2 keys
Phase Shift Keying (PSK)	Carrier: standard waveforms (except Pulse, DC, Noise), ARB; source internal or external; modulating waveform Square; key rate internal 500 uHz to 61 MHz, external 10 MHz max; hop frequency 0 to +360 degrees; 2 keys
Pulse Width Modulation (PWM)	Carrier Pulse; source internal or external; modulating waveforms Sine, Square, Ramp, Noise, ARB; modulating frequency internal 500 uHz to 61 MHz, external 10 MHz max; deviation range 0% to 50% of pulse period
Sweep	Linear, logarithmic, staircase, user defined; waveforms standard (except Pulse, DC, Noise), ARB; sweep time 30 ns to 2000 s; hold/return 0 to (2000 s - 30 ns); sweep/hold/return time resolution 15 ns or 12 digits; total sweep time accuracy less than or equal to 0.4%; start/stop range Sine 1 uHz to 1 GHz, Square 1 uHz to 385 MHz; trigger internal, external, or manual
Burst	Waveforms standard (except DC and Noise), ARB; trigger or gated; burst count 1 to 4,294,967,295 cycles or infinite
Timing and clock	Sampling rate 1 S/s up to 3 GS/s; resolution 32 Hz; accuracy plus or minus 2.0 ppm, plus or minus 500 ppb optional

9Digital Outputs (Optional)

Parameter	Specification
Connectors	Mini-SAS HD on rear panel (custom pin-out)
Number of connectors	1, 2, 4
Number of outputs	8 bits, 16 bits, 32 bits
Output impedance	100 ohms differential
Output type	LVDS
Rise/fall time (10% to 90%)	Less than 1 ns
Jitter (rms)	20 ps
Maximum update rate	750 Mbps per channel
Memory depth	512M samples per digital channel (up to 1G optional)

8-bit LVDS to LVTTL Converter Probe (Optional AT-DTLL8)

Optional 8-bit LVDS to LVTTL converter probe — Optional AT-DTLL8 LVDS to LVTTL converter probe.

Parameter	Specification
Output connector / type	20-position 2.54 mm 2-row IDC header; LVTTL
Output impedance	50 ohms nominal
Output voltage	0.8 V to 3.8 V, programmable in groups of 8 bits
Maximum update rate	125 Mbps at 0.8 V, 400 Mbps at 3.6 V
Dimensions	W 2 in x H 0.9 in x D 3 in [52 mm x 22 mm x 76 mm]
Input connector / cable	Proprietary standard; cable 1 meter, proprietary standard

Proprietary Mini-SAS HD to SMA Cable (Optional)

Proprietary Mini-SAS HD to SMA breakout cable for digital outputs — Optional Mini-SAS HD to SMA cable: 16 SMA connectors (8 bits) of LVDS digital output, 1 meter.

Parameter	Specification
Output connector / type	SMA; LVDS
Number of SMA	16 (8 bits)
Cable type / length	Proprietary standard; 1 meter

10Auxiliary Input and Output

Parameter	Specification
Sync in / out connector	Infiniband 4X on rear panel (custom pinout); master to slave delay (typical) TBD
Marker output connector	SMA on front panel; 1, 2, or 4 connectors
Marker output impedance	50 ohms
Marker output level (into 50 ohms)	Voltage window -0.5 V to 1.65 V; amplitude 100 mVpp to 2.15 Vpp; resolution 1 mV; accuracy plus or minus (5% setting + 25 mV)
Marker max update rate (True Arb)	3 Gbps; max data rate 3 Gbps at 1 Vpp swing
Marker max frequency (AFG)	96.5 MHz (continuous mode)
Marker rise/fall time (10% to 90%, 2 Vpp)	Less than 150 ps
Marker jitter (rms)	Less than 10 ps
Marker out to analog channel skew	Range True Arb 0 to 2.3 us, AFG 0 to 100 s continuous mode / 0 to 2.25 us trigger mode; resolution 1/32 of DAC sampling period, AFG 5 ps; accuracy plus or minus (1% of setting + 5 ps); initial skew less than 20 ps
External modulation input	SMA on rear panel; impedance 10 kohms; 1 input; bandwidth 10 MHz with 50 MS/s sampling rate; input range -1 V to +1 V (except FSK, PSK at 0 to 3.3 V with 1.65 V fixed threshold); 12-bit vertical resolution
Pattern Jump In (optional)	DSUB15; DATA[0..7] + Data Select + Load; 14-bit internal width, multiplexed using Data_Select; 16,384 addressable entries; data rate DC to 1 MHz; input range VIL 0 V to 0.8 V / VIH 2 V to 3.3 V; internal 1 kohm pull-up to Vcc (3.3 V)

11Clock & Reference

Parameter	Specification
Reference clock input	SMA on rear panel; 50 ohms AC coupled; input 0.2 Vpp to 2 Vpp; frequency 5 MHz to 200 MHz; resolution 1 Hz; damage level max input voltage -0.3 V to 3.6 V, max input power 30 dBm (50 ohms)
Reference clock output	SMA on rear panel; 50 ohms AC coupled; 10 MHz TCXO, 100 MHz VCOCXO optional; initial accuracy at 25 C plus or minus 1.0 ppm (500 ppb opt.); aging plus or minus 1.0 ppm/year (500 ppb/year opt.); stability vs. temperature plus or minus 1 ppm (50 ppb opt.); amplitude 1.65 Vpp
Reference clock phase noise (20 MHz carrier)	-120 dBc/Hz at 100 Hz; -140 dBc/Hz at 1 kHz; -150 dBc/Hz at 10 kHz
Reference clock phase noise (100 MHz carrier, opt.)	-120 dBc/Hz at 100 Hz; -145 dBc/Hz at 1 kHz; -150 dBc/Hz at 10 kHz
External clock input⁵	SMA on rear panel; 50 ohms AC coupled; True Arb SampleRate / N where N = 4, 8, 16, 32 for SampleRate = 5.0 to 6.16 GHz, N = 2, 4, 8, 16, 32 for SampleRate = 3.08 to 5.0 GHz; AFG 192.5 MHz, 385 MHz, 770 MHz, or 1540 MHz (selectable); input power +0 dBm to +10 dBm; damage level 15 dBm
Sync clock output	SMA on rear panel; 50 ohms AC coupled; frequency 2 × Sampling Rate / N, N = 16, 32, ..., 2048; amplitude 1 Vpp into 50 ohms

⁵ External clock SampleRate ranges (3.08 to 6.16 GHz) reproduced verbatim from the source data sheet.

12Trigger / Event Inputs

Parameter	Specification
Connector	SMA on front panel
Number of trigger inputs	2 (Trig.in 1, Trig.in 2)
Input impedance	50 ohms / 1 kohm
Slope / polarity	Positive, negative, or both
Input damage level	Below -15 V or above +15 V
Threshold control level / resolution	-10 V to 10 V; 50 mV
Threshold control accuracy	Plus or minus (10% of \|setting\| + 0.2 V)
Input voltage swing	0.5 Vp-p minimum
Minimum pulse width (1 Vp-p)	3 ns
Trigger/gate to analog output delay	Slow trigger: AFG < 355 ns (< 405 ns triggered sweep), True Arb < 1550 x DAC clock period (ns) + 10 ns. Fast trigger: AFG < 335 ns (< 385 ns triggered sweep), True Arb < 1360 x DAC clock period (ns) + 27 ns
Trigger-in to output jitter (rms)	AFG < 20 ps; True Arb 0.29 x DAC clock period
Programmable delay range / resolution	0 ps to 2418 ps; 78 ps
Maximum frequency	AFG 65 MTps rising/falling, 80 MTps both edges; True Arb 1 / (period of analog waveform + 48 DAC clock periods)

13System & Power

Parameter	Specification
Display	7 in, 1024 x 600, capacitive touch LCD
Operating system	Windows 10
External dimensions	W 17.6 in, H 5.4 in, D 12.6 in (3U 19-inch rack-mount) [445 mm x 135 mm x 320 mm]
Weight	Max. 26.45 lb (12 kg)
Front panel connectors	CH N OUTPUT (SMA, N = 2, 4, 8); MARKER N OUT (SMA, N = 1, 2, 4); TRG IN N (SMA, N = 1, 2); 2 USB 3.0 ports
Rear panel connectors	Ref. Clk. IN/OUT (SMA); Ext. Mod. IN (SMA); Sync Clk Out (SMA); Ext Clk IN (SMA); Sync IN/OUT (Infiniband 4X); Pattern Jump In (DSUB15, FSS option); POD X[7..0] (Mini-SAS HD); external monitor ports; USB 2.0 and 3.0; 10/100/1000BaseT Ethernet (RJ45); PS/2; DPI; DVI
Hard disk	1 TB SSD or better
Processor	Intel Pentium 3.7 GHz or better
Processor memory	32 GB or better
Remote interfaces	LAN, USB-TMC, GPIB
Source voltage and frequency	100 to 240 VAC plus or minus 10% at 45 to 66 Hz
Max. power consumption	100 W (685C-2C); 200 W (685C-4C); 300 W (685C-8C)

14Environmental, EMC & Safety

Parameter	Specification
Temperature (operating)	+41 F to 104 F [+5 C to +40 C]
Temperature (non-operating)	-4 F to 140 F [-20 C to +60 C]
Humidity (operating)	5% to 80% relative humidity with a maximum wet-bulb temperature of 84 F (29 C) at or below +104 F (40 C), upper limit de-rates to 20.6% relative humidity at +104 F (40 C). Non-condensing.
Humidity (non-operating)	5% to 95% relative humidity with a maximum wet-bulb temperature of 104 F (40 C) at or below +140 F (60 C), upper limit de-rates to 29.8% relative humidity at +140 F (60 C). Non-condensing.
Altitude (operating)	9,842 feet (3,000 meters) maximum at or below 77 F (25 C)
Altitude (non-operating)	39,370 feet (12,000 meters) maximum
Safety	EN61010-1
Main standards	EN 61326-1:2013, electrical equipment for measurement, control and laboratory use, EMC requirements, Part 1: General requirements
Immunity	EN 61326-1:2013

15Applications

The Model 685C combines a 3 GSa/s sampling rate with 16-bit vertical resolution, which makes it well suited to demanding test challenges across several industries.

Automotive

Today's cars include highly sophisticated and electronically controlled units with sensitive electronic components. The Model 685C combines a 3 GSa/s sampling rate with 16-bit vertical resolution. It represents an ideal and successful tool for addressing the new testing challenges in the automotive industry, including EMI debugging, troubleshooting, and testing, along with electrical standards emulation up to 5 V.

Semiconductor Testing

Emulation of complex signals generated with inclusion of noise or distortions may become an excellent way to provide Compliance Components Test to help semiconductor engineers. The fast edges and pulse generation can be used to provide characterization in fast power devices.

Research Applications

Research centers and universities are key users of the Model 685C. Complex waveform and sophisticated pulse emulation based on variable edges or multilevel could be perfectly created. The combination of fast edge generation, excellent dynamic range, and easy-to-use user interface meets the needs of scientists and engineers working on quantum research or on large experiments such as accelerators, tokamaks, or synchrotrons, to emulate signals without creating specific test boards.

Aerospace and Defense Applications

The Model 685C works perfectly with electronic warfare signals, such as those produced by radar or sonar systems. It can create pulses useful in pulsed electron beams, X-ray sources, flash X-ray radiography, lightning pulse simulators, and high-power microwave modulators. These features of Model 685C are useful in the aerospace and defense industry.

16Software & Support

The Model 685C runs a Windows 10 platform with an intuitive touchscreen interface for local operation, and it accepts remote control over LAN, USB-TMC, and GPIB. For programmatic control and integration into automated test systems, a software development kit is available.

Software Development Kit: Download the Model 685 series SDK (opens in a new window). 685C-specific SDK link (verify).

Request the full data sheet. For complete, current specifications and configuration details, request the published Model 685C data sheet through the Berkeley Nucleonics contact page (opens in a new window).

17Contact

For a quote, configuration help, or application support, reach the Berkeley Nucleonics team.

Email: info@berkeleynucleonics.com
Phone: 800-234-7858

For a quick question, chat with an engineer at berkeleynucleonics.com.