AWG M4x.66xx 16ビット、 625MS/s, 1.25GS/s、1,2,4チャネル

M4i AWG（高速任意波形発生器） M4i.66xx 16ビット、625MS/s, 1.25GS/s、1,2,4チャネル ・サンプリングレート 625MS/s：1/2/4チャネル 1.25GS/s：1/2チャネル ・出力電圧：±80mV～±2.5V （50Ω負荷）、±160mV～5V（1MΩ負荷） ・チャネル毎に独立した16ビットDAおよびアンプによる全チャネル同期出力 ・入力オフセット及び振幅：プログラマブル制御可能 ・出力：FIFO、Streaming、シングルショット、ループ、ゲート出力、シーケンス出力 ・マルチパーパスI/O信号（コネクタ）を使用して最大3出力までのマーカー出力可能 ・PCとの接続：PCIe Gen2 x8 製品名 分解能 出力チャネル サンプリングレート 帯域 M4i.6620-x8 16 1 625MS/s 200MHz M4i.6621-x8 16 2 625MS/s 200MHz M4i.6622-x8 16 4 625MS/s 200MHz M4i.6630-x8 16 1 1.25GS/s 400MHz M4i.6631-x8 16 2 1.25GS/s 400MHz

M4i.66xx-x8 - 16 bit 1.25 GS/s Arbitrary Waveform Generator • Fast 16 bit arbitrary waveform generator • One, two or four channels • Versions with 1.25 GS/s and 625 MS/s • Ouput signal bandwidth up to 400 MHz • Simultaneous signal generation on all channels • Output level ±80 mV to ±2.5 V (±2.0 V) into 50 Ω (±160 mV to ±5 V (±4 V) into high-impedance loads) • Fixed trigger to output delay • Ultra Fast PCI Express x8 Gen 2 interface • Huge 2 GSample on-board memory • FIFO mode continuous streaming output • Modes: Single-Shot, Loop, FIFO, Sequence Replay Mode, Gated, ... • Two trigger input/output with AND/OR functionality • Synchronization of up to 8 cards per system • PCIe x8 Gen 2 Interface • Works with x8/x16* PCIe slots • Sustained streaming mode more than 2.8 GB/s** Operating Systems Recommended Software Drivers • Windows 7 (SP1), 8, 10, • Visual C++, C++ Builder, Delphi • MATLAB Server 2008 R2 and newer GNU C++, VB.NET, C#, J#, Java, • LabVIEW • Linux Kernel 2.6, 3.x, 4.x, 5.x Python • IVI • Windows/Linux 32 and 64 bit • SBench 6 Model Bandwidth 1 channel 2 channels 4 channels General Information M4i.6630-x8 400 MHz 1.25 GS/s The M4i.66xx-x8 series arbitrary waveform digitizers deliver the highest M4i.6631-x8 400 MHz 1.25 GS/s 1.25 GS/s performance in both speed and resolution. The series includes PCIe M4i.6620-x8 200 MHz 625 MS/s cards with either one, two or four synchronous channels. The large on- M4i.6621-x8 200 MHz 625 MS/s 625 MS/s board memory can be segmented to replay different waveform sequenc- M4i.6622-x8 200 MHz 625 MS/s 625 MS/s 625 MS/s es. The AWG features a PCI Express x8 Gen 2 interface that offers outstand- ing data streaming performance. The interface and Spectrum’s opti- mized drivers enable data transfer rates in excess of 2.8 GB/s** so that signals can be continuously replayed at a high output rate. While the cards have been designed using the latest technology they are still software compatible with the drivers from earlier Spectrum waveform generator cards. So, existing customers can use the same software they developed for a 10 year old 20 MS/s AWG card and for an M4i series 1.25 GS/s AWG. *Some x16 PCIe slots are for the use of graphic cards only and can’t be used for other cards.**Throughput measured with a motherboard chipset supporting a TLP size of 256 bytes.SPECTRUM INSTRUMENTATION GMBH · AHRENSFELDER WEG 13-17 · 22927 GROSSHANSDORF · GERMANY 7.5.2020 PHONE: +49 (0)4102-6956-0 · FAX: +49 (0)4102-6956-66 · E-MAIL: info@spec.de · INTERNET: www.spectrum-instrumentation.com

and another set of CUDA parallel processing examples with easy building blocks for basic functions like filtering, averaging, data de- Software Support multiplexing, data conversion or FFT. All the software is based on C/C++ and can easily be implemented, expanded and modified Windows drivers with normal programming skills. The cards are delivered with drivers for Windows 7, Windows 8 and Windows 10 (32 bit and 64 bit). Programming examples for Third-party products Visual C++, C++ Builder, Delphi, Visual Basic, VB.NET, C#, J#, Py- Spectrum supports the most popular third-party software products thon, Java and IVI are included. such as LabVIEW, MATLAB or LabWindows/CVI. All drivers come with detailed documentation and working examples are included in Linux Drivers the delivery. Support for other software packages, like VEE or Da- All cards are delivered with full Linux support. Pre com- syLab, can also be provided on request. piled kernel modules are included for the most common distributions like Fedora, Suse, Ubuntu LTS or Debian. The Linux support includes SMP systems, 32 bit and 64 bit Hardware features and options systems, versatile programming examples for GNU C++, Python as well as the possibility to get the driver sources for your PCI Express x8 own compilation. The M4i series cards use a PCI Express x8 Gen 2 connection. They can be used in SBench 6 PCI Express x8 and x16 slots with Gen 1, Gen 2, Gen 3 or Gen4. The maximum A base license of sustained data transfer rate is more than SBench 6, the easy- 3.3 GByte/s (read direction) or 2.8 GByte/s (write direction) per to-use graphical oper- slot. Server motherboards often recognize PCI Express x1, x2 or x4 ating software for connections in x8 or x16 slots. These slots can also be used with Spectrum cards, is in- the M4i series cards but with reduced data transfer rates. cluded in the deliv- ery. The base license makes it is possible to Connections test the card, gener- • The cards are equipped with SMA connectors for the ate simple signals or analog signals as well as for the external trigger and load and replay pre- clock input. In addition, there are five MMCX connec- viously stored SBench tors that are used for an additional trigger input, a 6 signals. It's a valu- clock output and three multi-function I/O connectors. able tool for checking These multi-function connectors can be individually the cards perfor- programmed to perform different functions: mance and assisting • Trigger output with the units initial setup. The cards also come with a demo license • Status output (armed, triggered, ready, ...) for the SBench6 professional version. This license gives the user the • Synchronous digital inputs, being stored inside the analog data opportunity to test the additional features of the professional version samples with their hardware. The professional version contains several ad- • Asynchronous I/O lines vanced measurement functions, such as FFTs and X/Y display, im- port and export utilities as well as support for all replay modes Singleshot output including data streaming. Data streaming allows the cards to con- When singleshot output is activated the data of the on-board mem- tinuously replay data and transfer it directly from the PC RAM or ory is played exactly one time. The trigger source can be either one hard disk. SBench 6 has been optimized to handle data files of sev- of the external trigger inputs or the software trigger. After the first eral GBytes. SBench 6 runs under Windows as well as Linux (KDE trigger additional trigger events will be ignored. and GNOME) operating systems. A test version of SBench 6 can be downloaded directly over the internet and can run the profes- Repeated output sional version in a simulation mode without any hardware installed. Existing customers can also request a demo license for the profes- When the repeated output mode is used the data of the on-board sional version from Spectrum. More details on SBench 6 can be memory is played continuously for a programmed number of times found in the SBench 6 data sheet. or until a stop command is executed. The trigger source can be ei-ther one of the external trigger inputs or the software trigger. After the first trigger additional trigger events will be ignored. SCAPP – CUDA GPU based data processing For applications requiring External trigger input high performance signal All boards can be triggered using up to two external analog or dig- and data processing ital signals. One external trigger input has two analog comparators Spectrum offers SCAPP that can define an edge or window trigger, a hysteresis trigger or (Spectrum’s CUDA Access a rearm trigger. The other input has one comparator that can be for Parallel Processing). used for standard edge and level triggers. The SCAPP SDK allows a direct link between Spec- trum digitizers, AWGs or Single Restart replay Digital Data Acquisition When this mode is activated the data of the on-board memory will Cards and CUDA based GPU cards. Once in the GPU users can be replayed once after each trigger event. The trigger source can harness the processing power of the GPU’s multiple (up to 5000) be either the external TTL trigger or software trigger. processing cores and large (up to 24 GB) memories. SCAPP uses an RDMA (Linux only) process to send data at the full PCIe transfer FIFO mode speed to and from the GPU card. The SDK includes a set of exam- The FIFO mode is designed for continuous data transfer between ples for interaction between the Spectrum card and the GPU card PC memory or hard disk and the generation board. The control of

the data stream is done automatically by the driver on an interrupt sources can be combined with a logical OR allowing all channels request basis. The complete installed on-board memory is used for of all cards to be the trigger source at the same time. buffering data, making the continuous streaming extremely reliable. Multiple Replay The Multiple Replay mode al- lows the fast output genera- tion on several trigger events without restarting the hard- ware. With this option very fast repetition rates can be achieved. The on-board memory is divided into several segments of the same size. Each segment can contain different data which will then be played with the occurrence of each trigger event. Gated Replay The Gated Sampling mode al- lows data replay controlled by an external gate signal. Data is only replayed if the gate signal has attained a programmed level. Sequence Mode The sequence mode allows to split the card memory into sev- eral data segments of different length. These data segments are chained up in a user chosen order using an additional sequence memory. In this sequence memory the number of loops for each seg- ment can be programmed and trigger conditions can be defined to proceed from segment to segment. Using the sequence mode it is also possible to switch between replay waveforms by a simple soft- ware command or to redefine waveform data for segments simulta- neously while other segments are being replayed. All trigger- related and software-command-related functions are only working on single cards, not on star-hub-synchrnonized cards. External clock input and output Using a dedicated connector a sampling clock can be fed in from an external system. Additionally it’s also possible to output the in- ternally used sampling clock on a separate connector to synchro- nize external equipment to this clock. Reference clock The option to use a precise external reference clock (normally 10 MHz) is nec- essary to synchronize the instrument for high-quality measurements with external equipment (like a signal source). It’s also possible to enhance the quality of the sampling clock in this way. The driver automatically generates the requested sampling clock from the fed in reference clock. Star-Hub The Star-Hub is an additional module allowing the phase stable synchroniza- tion of up to 8 boards of a kind in one system. Independent of the number of boards there is no phase delay be- tween all channels. The Star-Hub dis- tributes trigger and clock information between all boards to ensure all con- nected boards are running with the same clock and trigger. All trigger

Technical Data Analog Outputs Resolution 16 bit D/A Interpolation no interpolation M4i.662x/M4x.662x M4i.663x/M4x.663x high bandwidth version DN2.662/DN6.662x DN2.663/DN6.663 (1.25 GS/s + option -hbw) Output amplitude into 50 Ω termination software programmable ±80 mV up to ±2.5 V ±80 mV up to ±2 V ±80 mV up to ±480 mV Output amplitude into high impedance loads software programmable ±160 mV up to ±5 V ±160 mV up to ±4 V ±160 mV up to ±960 mV Stepsize of output amplitude (50 Ω termination) 1 mV 1 mV 1 mV Stepsize of output amplitude (high impedance) 2 mV 2 mV 2 mV 10% to 90% rise/fall time of 480 mV pulse 1.06 ns 440 ps 10% to 90% rise/fall time of 2000 mV pulse 1.08 ns n.a. Output offset fixed 0 V Output Amplifier Path Selection automatically by driver Low Power path: ±80 mV to ±480 mV (into 50 Ω) High Power path: ±420 mV to ±2.5 V/±2 V (into 50 Ω) Output Amplifier Setting Hysteresis automatically by driver 420 mV to 480 mV (if output is using low power path it will switch to high power path at 480 mV. If output is using high power path it will switch to low power path at 420 mV) Output amplifier path switching time 10 ms (output disabled while switching) Filters software programmable bypass with no filter or one fixed filter DAC Differential non linearity (DNL) DAC only ±0.5 LSB typical DAC Integral non linearity (INL) DAC only ±1.0 LSB typical Output resistance 50 Ω Minimum output load 0 Ω (short circuit safe) Output accuracy Low power path ±0.5 mV ±0.1% of programmed output amplitude High power path ±1.0 mV ±0.2% of programmed output amplitude Trigger Available trigger modes software programmable External, Software, Window, Re-Arm, Or/And, Delay, PXI (M4x only) Trigger edge software programmable Rising edge, falling edge or both edges Trigger delay software programmable 0 to (8GSamples - 32) = 8589934560 Samples in steps of 32 samples Multi, Gate: re-arming time 40 samples Trigger to Output Delay sample rate ≤ 625 MS/s 238.5 sample clocks + 16 ns sample rate > 625 MS/s 476.5 sample clocks + 16 ns Memory depth software programmable 32 up to [installed memory / number of active channels] samples in steps of 32 Multiple Replay segment size software programmable 16 up to [installed memory / 2 / active channels] samples in steps of 16 Trigger accuracy (all sources) 1 sample Minimum external trigger pulse width ≥ 2 samples External trigger Ext0 Ext1 External trigger impedance software programmable 50 Ω /1 kΩ 1 kΩ External trigger coupling software programmable AC or DC fixed DC External trigger type Window comparator Single level comparator External input level ±10 V (1 kΩ), ±2.5 V (50 Ω), ±10 V External trigger sensitivity 2.5% of full scale range 2.5% of full scale range = 0.5 V (minimum required signal swing) External trigger level software programmable ±10 V in steps of 10 mV ±10 V in steps of 10 mV External trigger maximum voltage ±30V ±30 V External trigger bandwidth DC 50 Ω DC to 200 MHz n.a. 1 kΩ DC to 150 MHz DC to 200 MHz External trigger bandwidth AC 50 Ω 20 kHz to 200 MHz n.a. Minimum external trigger pulse width ≥ 2 samples ≥ 2 samples

Clock Clock Modes software programmable internal PLL, external reference clock, Star-Hub sync (M4i only), PXI Reference Clock (M4x only) Internal clock accuracy ≤ ±20 ppm Internal clock setup granularity 8 Hz (internal reference clock only, restrictions apply to external reference clock) Setable Clock speeds 50 MHz to max sampling clock Clock Setting Gaps 750 to 757 MHz, 1125 to 1145 MHz (no sampling clock possible in these gaps) External reference clock range software programmable ≥ 10 MHz and ≤ 1.25 GHz External reference clock input impedance 50 Ω fixed External reference clock input coupling AC coupling External reference clock input edge Rising edge External reference clock input type Single-ended, sine wave or square wave External reference clock input swing 0.3 V peak-peak up to 3.0 V peak-peak External reference clock input max DC voltage ±30 V (with max 3.0 V difference between low and high level) External reference clock input duty cycle requirement 45% to 55% External reference clock output type Single-ended, 3.3V LVPECL Clock output sampling clock ≤71.68 MHz Clock output = sampling clock/4 Clock output sampling clock >71.68 MHz Clock output = sampling clock/8 Star-Hub synchronization clock modes software selectable Internal clock, external reference clock Sequence Replay Mode (Mode available starting with firmware V1.14) Number of sequence steps software programmable 1 up to 4096 (sequence steps can be overloaded at runtime) Number of memory segments software programmable 2 up to 64k (segment data can be overloaded at runtime) Minimum segment size software programmable 384 samples (1 active channel), 192 samples (2 active channels), 96 samples (4 active channels), in steps of 32 samples. Maximum segment size software programmable 2 GS / active channels / number of sequence segments (round up to the next power of two) Loop Count software programmable 1 to (1M - 1) loops Sequence Step Commands software programmable Loop for #Loops, Next, Loop until Trigger, End Sequence Special Commands software programmable Data Overload at runtime, sequence steps overload at runtime, readout current replayed sequence step Limitations for synchronized products Software commands changing the sequence as well as „Loop until trigger“ are not synchronized between cards. This also applies to multiple AWG modules in a generatorNETBOX. Multi Purpose I/O lines (front-plate) Number of multi purpose lines three, named X0, X1, X2 Input: available signal types software programmable Asynchronous Digital-In Input: impedance 10 kΩ to 3.3 V Input: maximum voltage level -0.5 V to +4.0 V Input: signal levels 3.3 V LVTTL Output: available signal types software programmable Asynchronous Digital-Out, Synchronous Digital-Out, Trigger Output, Run, Arm, Marker Output, System Clock Output: impedance 50 Ω Output: signal levels 3.3 V LVTTL Output: type 3.3V LVTTL, TTL compatible for high impedance loads Output: drive strength Capable of driving 50 Ω loads, maximum drive strength ±48 mA Output: update rate sampling clock

Bandwidth and Slewrate Filter Output Amplitude M4i.6630-x8 M4i.6620-x8 M4i.6631-x8 M4i.6621-x8 DN2.663-xx M4i.6622-x8 DN2.662-xx Maximum Output Rate 1.25 GS/s 625 MS/s -3dB Bandwidth no Filter ±480 mV 400 MHz 200 MHz -3dB Bandwidth no Filter ±1000 mV 320 MHz 200 MHz -3dB Bandwidth no Filter ±2000 mV 320 MHz 200 MHz -3dB Bandwidth Filter all 65 MHz 65 MHz Slewrate no Filter ±480 mV 4.5 V/ns 2.25 V/ns Dynamic Parameters M4i.6620-x8 M4i.6621-x8 M4i.6622-x8 DN2.662-xx Test - Samplerate 625 MS/s 625 MS/s 625 MS/s Output Frequency 10 MHz 50 MHz 50 MHz Output Level in 50 Ω ±480 mV ±1000mV ±2500mV ±480 mV ±2500mV ±480 mV ±2500mV Used Filter none none Filter enabled NSD (typ) -150 dBm/Hz -149 dBm/Hz -149 dBm/Hz -150 dBm/Hz -149 dBm/Hz -150 dBm/Hz -149 dBm/Hz SNR (typ) 70.7 dB 72.4 dB 63.1 dB 65.3 dB 64.4 dB 67.5 dB 69.4 dB THD (typ) -73.3 dB -70.5 dB -49.7 dB -64.1 dB -39.1 dB -68.4 dB -50.4 dB SINAD (typ) 69.0 dB 67.7 dB 49.5 dB 61.6 dB 39.1 dB 64.9 dB 50.3 dB SFDR (typ), excl harm. 98 dB 98 dB 99 dB 86 dB 76 dB 88 dB 89 dB ENOB (SINAD) 11.2 11.0 8.0 10.0 6.2 10.5 8.1 ENOB (SNR) 11.5 11.7 10.2 10.5 10.4 10.9 11.2 M4i.6630-x8 M4i.6631-x8 DN2.663-xx Test - Samplerate 1.25 GS/s 1.25 GS/s 1.25 GS/s Output Frequency 10 MHz 50 MHz 50 MHz Output Level in 50 Ω ±480 mV ±1000mV ±2000mV ±480 mV ±2000mV ±480 mV ±2000mV Used Filter none none Filter enabled NSD (typ) -150 dBm/Hz -149 dBm/Hz -149 dBm/Hz -150 dBm/Hz -149 dBm/Hz -150 dBm/Hz -149 dBm/Hz SNR (typ) 70.5 dB 72.1 dB 71.4 dB 65.2 dB 65.0 dB 67.2 dB 68.2 dB THD (typ) -74.5 dB -73.5 dB -59.1 dB -60.9 dB -43.9 dB -67.9 dB -63.1 dB SINAD (typ) 69.3 dB 69.7 dB 59 dB 59.5 dB 43.9 dB 64.5 dB 61.9 dB SFDR (typ), excl harm. 96 dB 97 dB 98 dB 85 dB 84 dB 87 dB 87 dB ENOB (SINAD) 11.2 11.2 9.5 9.6 6.9 10.4 10.0 ENOB (SNR) 11.5 11.5 11.5 10.5 10.5 10.9 11.0 T HD and SFDR are measured at the given output level and 50 Ohm termination with a high resolution M3i.4860/M4i.4450-x8 data acquisition card and are calculated from the spec- trum. Noise Spectral Density is measured with built-in calculation from an HP E4401B Spectrum Analyzer. All available D/A channels are activated for the tests. SNR and SFDR figures may differ depending on the quality of the used PC. NSD = Noise Spectral Density, THD = Total Harmonic Distortion, SFDR = Spurious Free Dynamic Range. SFDR and THD versus signal frequency • Measurements done with a spectrum analyzer bandwidth of 1.5 GHz • Please note that the bandwidth of the high range output is limited to 320 MHz • Please note that the output bandwidth limit also affects the THD as harmonics higher than the bandwidth are filtered

Connectors Analog Inputs/Analog Outputs SMA female (one for each single-ended input) Cable-Type: Cab-3mA-xx-xx Trigger 0 Input SMA female Cable-Type: Cab-3mA-xx-xx Clock Input SMA female Cable-Type: Cab-3mA-xx-xx Trigger 1 Input MMCX female Cable-Type: Cab-1m-xx-xx Clock Output MMCX female Cable-Type: Cab-1m-xx-xx Multi Purpose I/O MMCX female (3 lines) Cable-Type: Cab-1m-xx-xx Environmental and Physical Details Dimension (Single Card) 241 mm (¾ PCIe length) x 107 mm x 20 mm (single slot width) Dimension (Card with option SH8tm installed) 241 mm (¾ PCIe length) x 107 mm x 40 mm (double slot width) Dimension (Card with option SH8ex installed) 312 mm (full PCIe length) x 107 mm x 20 mm (single slot width) Weight (M4i.44xx series) maximum 290 g Weight (M4i.22xx, M4i.66xx, M4i.77xx series) maximum 420 g Weight (Option star-hub -sh8ex, -sh8tm) including 8 sync cables 130 g Warm up time 10 minutes Operating temperature 0°C to 50°C Storage temperature -10°C to 70°C Humidity 10% to 90% PCI Express specific details PCIe slot type x8 Generation 2 PCIe slot compatibility (physical) x8/x16 PCIe slot compatibility (electrical) x1, x2, x4, x8, x16 with Generation 1, Generation 2, Generation 3, Generation 4 Sustained streaming mode > 3.4 GB/s (measured with a chipset supporting a TLP size of 256 bytes, using PCIe x8 Gen2) (Card-to-System: M4i.22xx, M4i.44xx, M4i.77xx) Sustained streaming mode > 2.8 GB/s (measured with a chipset supporting a TLP size of 256 bytes, using PCIe x8 Gen2) (System-to-Card: M4i.66xx) Certification, Compliance, Warranty EMC Immunity Compliant with CE Mark EMC Emission Compliant with CE Mark Product warranty 5 years starting with the day of delivery Software and firmware updates Life-time, free of charge Power Consumption PCI EXPRESS 3.3V 12 V Total M4i.6620-x8 Typical values: All channels activated, Sample rate: 625 MSps 0.2 A 2.5 A 31 W M4i.6621-x8 Output signal: 31.25 MHz sine wave, Output level: +/- 1 V into 50 Ω load 0.2 A 2.7 A 33 W M4i.6622-x8 0.2 A 3.0 A 36 W M4i.6620-x8 Typical values: All channels activated, Sample rate: 625 MSps 0.2 A 2.6 A 32 W M4i.6621-x8 Output signal: 31.25 MHz sine wave, Output level: +/- 2.5 V into 50 Ω load 0.2 A 2.9 A 35 W M4i.6622-x8 0.2 A 3.3 A 40 W M4i.6630-x8 Typical values: All channels activated, Sample rate: 1.25 GSps 0.2 A 2.7 A 33 W M4i.6631-x8 Output signal: 31.25 MHz sine wave, Output level: +/- 1 V into 50 Ω load 0.2 A 3.0 A 36 W M4i.6630-x8 Typical values: All channels activated, Sample rate: 1.25 GSps 0.2 A 2.9 A 35 W M4i.6631-x8 Output signal: 31.25 MHz sine wave, Output level: +/- 2.0 V into 50 Ω load 0.2 A 3.3 A 40 W MTBF MTBF 100000

Hardware block diagram

Order Information The card is delivered with 2 GSample on-board memory and supports standard replay, FIFO replay (streaming), Multiple Replay, Gated Replay, Continuous Replay (Loop), Single-Restart as well as Sequence. Operating system drivers for Windows/Linux 32 bit and 64 bit, ex- amples for C/C++, LabVIEW (Windows), MATLAB (Windows and Linux), IVI, .NET, Delphi, Java, Python and a Base license of the measure- ment software SBench 6 are included. Adapter cables are not included. Please order separately! PCI Express x8 Order no. Bandwidth Standard mem 1 channel 2 channels 4 channels M4i.6620-x8 200 MHz 2 GSample 625 MS/s M4i.6621-x8 200 MHz 2 GSample 625 MS/s 625 MS/s M4i.6622-x8 200 MHz 2 GSample 625 MS/s 625 MS/s 625 MS/s M4i.6630-x8 400 MHz 2 GSample 1.25 GS/s M4i.6631-x8 400 MHz 2 GSample 1.25 GS/s 1.25 GS/s Options Order no. Option M4i.xxxx-SH8ex (1) Synchronization Star-Hub for up to 8 cards (extension), only one slot width, extension of the card to full PCI Express length (312 mm). 8 synchronization cables included. M4i.xxxx-SH8tm (1) Synchronization Star-Hub for up to 8 cards (top mount), two slots width, top mounted on card. 8 syn- chronization cables included. M4i-upgrade Upgrade for M4i.xxxx: Later installation of option Star-Hub Options Order no. Option M4i.663x-hbw High bandwidth option 600 MHz. Output level limited to ±480 mV into 50 Ω. Needs external recon- struction filter. One option needed per AWG card. Standard Cables Order no. for Connections Length to BNC male to BNC female to SMA male to SMA female to SMB female Analog/Clock-In/Trig-In 80 cm Cab-3mA-9m-80 Cab-3mA-9f-80 Cab-3mA-3mA-80 Cab-3f-3mA-80 Analog/Clock-In/Trig-In 200 cm Cab-3mA-9m-200 Cab-3mA-9f-200 Cab-3mA-3mA-200 Cab-3f-3mA-200 Probes (short) 5 cm Cab-3mA-9f-5 Clk-Out/Trig-Out/Extra 80 cm Cab-1m-9m-80 Cab-1m-9f-80 Cab-1m-3mA-80 Cab-1m-3fA-80 Cab-1m-3f-80 Clk-Out/Trig-Out/Extra 200 cm Cab-1m-9m-200 Cab-1m-9f200 Cab-1m-3mA-200 Cab-1m-3fA-200 Cab-1m-3f-200 Information The standard adapter cables are based on RG174 cables and have a nominal attenuation of 0.3 dB/m at 100 MHz and 0.5 dB/m at 250 MHz. For high speed signals we recommend the low loss cables series CHF Services Order no. Recal Recalibration at Spectrum incl. calibration protocol Low Loss Cables Order No. Option CHF-3mA-3mA-200 Low loss cables SMA male to SMA male 200 cm CHF-3mA-9m-200 Low loss cables SMA male to BNC male 200 cm Information The low loss adapter cables are based on MF141 cables and have an attenuation of 0.3 dB/m at 500 MHz and 0.5 dB/m at 1.5 GHz. They are recommended for signal frequencies of 200 MHz and above. Software SBench6 Order no. SBench6 Base version included in delivery. Supports standard mode for one card. SBench6-Pro Professional version for one card: FIFO mode, export/import, calculation functions SBench6-Multi Option multiple cards: Needs SBench6-Pro. Handles multiple synchronized cards in one system. Volume Licenses Please ask Spectrum for details. Software Options Order no. SPc-RServer Remote Server Software Package - LAN remote access for M2i/M3i/M4i/M4x/M2p cards SPc-SCAPP Spectrum’s CUDA Access for Parallel Processing - SDK for direct data transfer between Spectrum card and CUDA GPU. Includes RDMA activation and examples. Signed NDA needed for access. (1) : Just one of the options can be installed on a card at a time. (2) : Third party product with warranty differing from our export conditions. No volume rebate possible. Technical changes and printing errors possible SBench, digitizerNETBOX and generatorNETBOX are registered trademarks of Spectrum Instrumentation GmbH. Microsoft, Visual C++, Windows, Windows 98, Windows NT, Window 2000, Windows XP, Windows Vista, Windows 7, Windows 8 and Windows 10 are trademarks/registered trademarks of Microsoft Corporation. LabVIEW, DASYLab, Diadem and LabWindows/CVI are trademarks/registered trademarks of National Instruments Corporation. MATLAB is a trademark/registered trademark of The Mathworks, Inc. Delphi and C++Builder are trademarks/registered trademarks of Embarcadero Technologies, Inc. Keysight VEE, VEE Pro and VEE OneLab are trademarks/registered trademarks of Keysight Technologies, Inc. FlexPro is a registered trademark of Weisang GmbH & Co. KG. PCIe, PCI Express and PCI-X and PCI-SIG are trademarks of PCI-SIG. LXI is a registered trademark of the LXI Consortium. PICMG and CompactPCI are trademarks of the PCI Industrial Computation Manufacturers Group. Oracle and Java are registered trademarks of Oracle and/or its affiliates. Intel and Intel Core i3, Core i5, Core i7, Core i9 and Xeon are trademarks and/or registered trademarks of Intel Corporation. AMD, Opteron, Sempron, Phenom, FX, Ryzen and EPYC are trademarks and/or registered trademarks of Advanced Micro Devices. NVIDIA, CUDA, GeForce, Quadro and Tesla are trademarks/registered trademarks of NVIDIA Corporation.