AWG NETBOX DN6.65x 16ビット、 40MS/s, 125MS/s、24, 32, 40, 48チャネル

generatorNETBOX DN6.65x 16ビット、40MS/s, 125MS/s 任意波形発生器 ・サンプリングレート 40MS/s：24/32/40/48チャネル 80MS/s: 24/32/40/48チャネル 125MS/s： 12/16/20/24チャネル すべてのチャネル同期出力 ・出力電圧 ハイインピーダンス時の出力レベル ：±6V 50オーム時の出力レベル :±3V ・シングルショット、ループ、ゲートモード、シーケンス・モード ・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 製品名 分解能 出力チャネル サンプリングレート 帯域 DN6.653-24 16 24 40MS/s 20MHz DN6.653-32 16 32 40MS/s 20MHz DN6.653-40 16 40 40MS/s 20MHz DN6.653-48 16 48 40MS/s 20MHz 125MS/s（12チャネル時） DN6.656-24 16 24 80MS/s（24チャネル時） 70MHz 125MS/s（16チャネル時） DN6.656-32 16 32 80MS/s（32チャネル時） 70MHz 125MS/s（24チャネル時） DN6.656-40 16 40 70MHz 80MS/s（40チャネル時） 125MS/s（24チャネル時） DN6.656-48 16 48 70MHz 80MS/s（48チャネル時）

DN6.65x - 48 channel 16 bit generatorNETBOX up to 125 MS/s • 24, 32, 40 or 48 channels with 40 MS/s up to 125 MS/s • Simultaneous arbitrary generation on all channels • Output level ±3.0 V into 50 Ω (±6 V into high-impedance loads) • Fixed trigger to output delay • Large 64 MSample per channel internal memory • FIFO mode continuous streaming output • Modes: Single-Shot, Loop, FIFO, Sequence Replay Mode, Gated, ... • Ethernet Remote Instrument • Direct Connection to PC/Laptop • LXI Core 2011 compatible • Connect anywhere in company LAN • GBit Ethernet Interface • Embedded Webserver for Maintenance/Updates • Sustained streaming mode up to 100 MB/s • Embedded Server option for open Linux platform Operating Systems SBench 6 Professional Included Drivers • Windows 7 (SP1), 8, 10, • Acquisition, Generation and Display of analog and • LabVIEW, MATLAB, LabWindows/CVI Server 2008 R2 and newer digital data • C/C++, GNU C++, VB.NET, C#, J#, • Linux Kernel 2.6, 3.x, 4.x, 5.x • Calculation, FFT Delphi, Java, Python • Windows/Linux 32 and 64 bit • Documentation and Import, Export • IVI Analog output channels Output Level Internal General Information Model Channels Speed in 50Ω in 1 MΩ Star-Hub Modules The general purpose Ethernet-AWG series DN6.653-24 24 40 MS/s ±3 V ±6 V yes 3 generatorNETBOX DN6.65x allows generation of DN6.653-32 32 40 MS/s ±3 V ±6 V yes 4 arbitrary signals on up to 48 channels in parallel. These DN6.653-40 40 40 MS/s ±3 V ±6 V yes 5 Ethernet Remote instruments offer outstanding D/A DN6.653-48 48 40 MS/s ±3 V ±6 V yes 6 features both in resolution and signal quality. DN6.656-24 12 125 MS/s ±3 V ±6 V yes 3 24 80 MS/s The combination of high sampling rate and resolution DN6.656-32 16 125 MS/s ±3 V ±6 V yes 4 makes these AWGs the top-of-the-range for applications 32 80 MS/s that require high quality signal generation. DN6.656-40 20 125 MS/s ±3 V ±6 V yes 5 40 80 MS/s The generatorNETBOX can be installed anywhere in the DN6.656-48 24 125 MS/s ±3 V ±6 V yes 6 company LAN and can be remotely controlled from a host 48 80 MS/s PC.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

Software Support driver supports IVI Scope, IVI Digitizer and IVI FGen class with IVI- C and IVI-COM interfaces. Windows Support The digitizerNETBOX/generatorNETBOX can be accessed from Third-party Software Products Windows 7, Windows 8,Windows 10 (each 32 bit and 64 bit). Most popular third-party software products, such as LabVIEW, Programming examples for Visual C++, C++ Builder, LabWin- MATLAB or LabWindows/CVI are supported. All drivers come dows/CVI, Delphi, Visual Basic, VB.NET, C#, J#, Python, Java and with examples and detailed documentation. IVI are included. Embedded Webserver Linux Support The integrated webserver The digitizerNETBOX/generatorNETBOX can be access- follows the LXI standard ed from any Linux system. The Linux support includes SMP and gathers information systems, 32 bit and 64 bit systems, versatile program- on the product, set up of ming examples for Gnu C++, Python as well as drivers for the Ethernet configuration MATLAB for Linux. SBench 6, the powerful data acquisi- and current status. It also tion and analysis software from Spectrum is also included as a Linux allows the setting of a con- version. figuration password, ac- cess to documentation Discovery Protocol and updating of the com- plete instrument firmware, The Discovery function including the embedded helps you to find and remote server and the identify any Spectrum LXI webserver. instruments, like the digitizerNETBOX and generatorNETBOX, avail- Hardware features and options able to your computer on the network. The Discovery function will also locate any Spectrum card products that are managed by an LXI Instrument installed Spectrum Remote Server somewhere on the network. The digitizerNETBOX and generatorNETBOX are fully After running the discovery function the card information is cached LXI instrument compatible and can be directly accessed by SBench 6. Furthermore the quali- to LXI Core 2011 following fied VISA address is returned and can be used by any software to the LXI Device Specification access the remote instrument. 2011 rev. 1.4. The digitizerNETBOX/generatorNETBOX has been tested and approved by the LXI Consortium. SBench 6 Professional The digitizerNETBOX and Located on the front panel is the main on/off switch, LEDs showing generatorNETBOX can be used the LXI and Acquisition status and the LAN reset switch. with Spectrum’s powerful software SBench 6 – a Professional license Front Panel for the software is already in- Standard BNC connectors are used stalled in the box. SBench 6 sup- for all analog input or output sig- ports all of the standard features of nals and all auxiliary signals like the instrument. It has a variety of clock and trigger. No special display windows as well as analy- adapter cables are needed and the sis, export and documentation connection is secure even when functions. used in a moving environment. • Available for Windows XP, Vista, Windows 7, Windows 8, Custom front panels are available Windows 10 and Linux on request even for small series, be it SMA, LEMO connectors or • Easy to use interface with drag and drop, docking windows and custom specific connectors. context menus • Display of analog and digital data, X-Y display, frequency Ethernet Connectivity domain and spread signals • Designed to handle several GBytes of data The GBit Ethernet connection can be • Fast data preview functions used with standard COTS Ethernet cabling. The integration into a stan- dard LAN allows to connect the IVI Driver digitizerNETBOX/generatorNET- The IVI standards define an open driver architecture, a set of instru- BOX either directly to a desktop PC ment classes, and shared software components. Together these pro- or Laptop or it is possible to place vide critical elements needed for instrument interchangeability. IVI's the instrument somewhere in the defined Application Programming Interfaces (APIs) standardize company LAN and access it from any desktop over the LAN. common measurement functions reducing the time needed to learn a new IVI instrument. Boot on Power on Option The digitizerNETBOX/generatorNETBOX can be factory config- The Spectrum products to be accessed with the IVI driver can be lo- ured to automatically start and boot upon availability of the input cally installed data acquisition cards, remotely installed data acqui- power rail. That way the instrument will automatically become sition cards or remote LXI instruments like available again upon loss of input power. digitizerNETBOX/generatorNETBOX. To maximize the compatibil- ity with existing IVI based software installations, the Spectrum IVI

Option Embedded Server gate signal has attained a programmed level. The option turns the digitizer- NETBOX/generatorNETBOX Sequence Mode in a powerful PC that allows to The sequence run own programs on a small mode allows to and remote data acquisition split the card system. The digitizerNET- memory into sev- BOX/generatorNETBOX is en- eral data segments of different length. These data segments are hanced by more memory, a powerful CPU, a freely accessable chained up in a user chosen order using an additional sequence internal SSD and a remote software development access method. memory. In this sequence memory the number of loops for each seg- ment can be programmed and trigger conditions can be defined to The digitizerNETBOX/generatorNETBOX can either run connected proceed from segment to segment. Using the sequence mode it is to LAN or it can run totally independent, storing data to the internal also possible to switch between replay waveforms by a simple soft- SSD. The original digitizerNETBOX/generatorNETBOX remote in- ware command or to redefine waveform data for segments simulta- strument functionality is still 100 % available. Running the embed- neously while other segments are being replayed. All trigger- ded server option it is possible to pre-calculate results based on the related and software-command-related functions are only working acquired data, store acquisitions locally and to transfer just the re- on single cards, not on star-hub-synchrnonized cards. quired data or results parts in a client-server based software struc- ture. A different example for the External trigger input digitizerNETBOX/generatorNETBOX embedded server is surveil- lance/logger application which can run totally independent for All boards can be triggered using up to two external analog or dig- days and send notification emails only over LAN or offloads stored ital signals. One external trigger input has two analog comparators data as soon as it’s connected again. that can define an edge or window trigger, a hysteresis trigger or a rearm trigger. The other input has one comparator that can be Access to the embedded server is done through a standard text used for standard edge and level triggers. based Linux shell based on the ssh secure shell. External clock input and output Singleshot output Using a dedicated connector a sampling clock can be fed in from When singleshot output is activated the data of the on-board mem- an external system. Additionally it’s also possible to output the in- ory is played exactly one time. The trigger source can be either one ternally used sampling clock on a separate connector to synchro- of the external trigger inputs or the software trigger. After the first nize external equipment to this clock. trigger additional trigger events will be ignored. Reference clock Repeated output The option to use a precise When the repeated output mode is used the data of the on-board external reference clock memory is played continuously for a programmed number of times (normally 10 MHz) is nec- or until a stop command is executed. The trigger source can be ei- essary to synchronize the ther one of the external trigger inputs or the software trigger. After instrument for high-quality the first trigger additional trigger events will be ignored. 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 Single Restart replay clock from the fed in reference clock. When this mode is activated the data of the on-board memory will be replayed once after each trigger event. The trigger source can be either the external TTL trigger or software trigger. FIFO mode The FIFO mode is designed for continuous data transfer between PC memory or hard disk and the generation board. The control of the data stream is done automatically by the driver on an interrupt request basis. The complete installed on-board memory is used for 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

DN2 / DN6 Technical Data Analog Outputs Resolution 16 bit D/A Interpolation no interpolation Output amplitude software programmable 653x and 656x: ±1 mV up to ±3 V in 1 mV steps into 50 Ω termination (resulting in ±2 mV up to ±6 V in 2mV steps into high impedance loads) 654x and 657x: ±1 mV up to ±6 V in 1 mV steps into 50 Ω termination (resulting in ±2 mV up to ±12 V in 2mV steps into high impedance loads) Note: Gain values below ±300 mV into 50 Ω are reduced by digital scaling of the samples Output Amplifier Path Selection automatically by driver Low Power path: Selected Gain of ±1 mV to ±960 mV (into 50 Ω) High Power path: 653x and 656x: Selected Gain of ±940 mV to ±3 V (into 50 Ω) 654x and 657x: Selected Gain of ±940 mV to ±6 V (into 50 Ω) Output Amplifier Setting Hysteresis automatically by driver 940 mV to 960 mV (if output is using low power path it will switch to high power path at 960 mV. If output is using high power path it will switch to low power path at 940 mV) Output amplifier path switching time 1.2 ms (output disabled while switching) Output offset software programmable Low Power path: ±960 mV in 1 mV steps into 50 Ω (±1920 mV in 2 mV steps into 1 MΩ) High Power path: 653x and 656x: ±3 V in 1 mV steps into 50 Ω (±6V in 2 mV steps into 1 MΩ) 654x and 657x: ±6 V in 1 mV steps into 50 Ω (±12V in 2 mV steps into 1 MΩ) Filters software programmable One of 4 different filters (refer to „Bandwidth and Filters“ section) DAC Differential non linearity (DNL) DAC only ±2.0 LSB typical DAC Integral non linearity (INL) DAC only ±4.0 LSB typical Output resistance 50 Ω Minimum output load 653x and 656x: 0 Ω (short circuit safe by design) 654x and 657x: 50 Ω (short circuit safe by hardware supervisor, outputs will turn off) Max output swing in 50 Ω 653x and 656x: ±3.0 V (offset + amplitude) 654x and 657x: ±6.0 V (offset + amplitude) Max output swing in 1 MΩ 653x and 656x: ±6.0 V (offset + amplitude) 654x and 657x: ±12.0 V (offset + amplitude) Slewrate (using Filter 0) Low power path (0 to 900 mV): 250 mV/ns 653x and 656x: High power path (0 to 3000 mV): 850 mV/ns 654x and 657x: High power path (0 to 6000 mV): TBD Crosstalk @ 1 MHz signal ±3 V 1 to 4 ch standard AWG 95 dB (M2p.6530, M2p.6531, M2p.6536, M2p.6560, M2p.6561, M2p.6566) Crosstalk @ 1 MHz signal ±3 V 8 channel AWG 84 dB (M2p.6533, M2p.6568) Crosstalk @ 1 MHz signal ±6 V 1 to 4 ch high-voltage AWG 99 dB (M2p.6540, M2p.6541, M2p.6546, M2p.6540, M2p.6541, M2p.6546) Output accuracy ±1 mV ±0.5 % of programmed output amplitude ±0.1 % of programmed output offset Trigger Available trigger modes software programmable External, Software, Pulse, Or/And, Delay Trigger edge software programmable Rising edge, falling edge or both edges Trigger pulse width software programmable 0 to [4G - 1] samples in steps of 1 sample Trigger delay software programmable 0 to [4G - 1] samples in steps of 1 samples Trigger holdoff (for Multi, Gate) software programmable 0 to [4G - 1] samples in steps of 1 samples Multi, Gate: re-arming time < 24 samples (+ programmed holdoff) Trigger to Output Delay 63 sample clocks + 7 ns Memory depth software programmable 16 up to [installed memory / number of active channels] samples in steps of 8 Multiple Replay segment size software programmable 8 up to [installed memory / number of active channels] samples in steps of 8 External trigger accuracy 1 sample External trigger Ext X1, X2, X3 External trigger type Single level comparator 3.3V LVTTL logic inputs External trigger impedance software programmable 50 Ω / 5 kΩ For electrical specifications refer to External trigger input level ±5 V (5 kΩ), ±2.5 V (50 Ω), „Multi Purpose I/O lines“ section. External trigger over voltage protection ±20 V (5 kΩ), 5 Vrms (50 Ω) External trigger sensitivity 200 mVpp (minimum required signal swing) External trigger level software programmable ±5 V in steps of 1 mV External trigger bandwidth 50 Ω DC to 400 MHz n.a. 5 kΩ DC to 300 MHz DC to 125 MHz Minimum external trigger pulse width ≥ 2 samples ≥ 2 samples

Multi Purpose I/O lines Number of multi purpose output lines one, named X0 Number of multi purpose input/output lines three, named X1, X2, X3 Multi Purpose line X0 X1, X2, X3 Input: available signal types software programmable n.a. Asynchronous Digital-In, Logic trigger Input: signal levels n.a. 3.3 V LVTTL Input: impedance n.a. 10 kΩ to 3.3 V Input: maximum voltage level n.a. -0.5 V to +4.0 V Input: maximum bandwidth n.a. 125 MHz Output: available signal types software programmable Run-, Arm-, Trigger-Output, Run-, Arm-, Trigger-Output, Marker-Output, Synchronous Digital-Out, Marker-Output, Synchronous Digital-Out, Asynchronous Digital-Out Asynchronous Digital-Out, ADC Clock Output, Output: impedance 50 Ω Output: drive strength Capable of driving 50 Ω loads, maximum drive strength ±48 mA Output: type / signal levels 3.3V LVTTL, TTL compatible for high impedance loads Output: update rate (synchronous modes) sampling clock Sequence Replay Mode 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 32 samples in steps of 8 samples. Maximum segment size software programmable 512 MS / 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. Clock Clock Modes software programmable internal PLL, external clock, external reference clock, sync Internal clock range (PLL mode) software programmable see „Clock Limitations“ table below Internal clock accuracy after warm-up ≤ ±1.0 ppm (at time of calibration in production) Internal clock aging ≤ ±0.5 ppm / year PLL clock setup granularity (int. or ext. reference) 1 Hz External reference clock range software programmable 128 kHz up to 125 MHz Direct external clock to internal clock delay 4.3 ns Direct external clock range see „Clock Limitations and Bandwidth“ table below External clock type Single level comparator External clock input level ±5 V (5 kΩ), ±2.5 V (50 Ω), External clock input impedance software programmable 50 Ω / 5 kΩ External clock over voltage protection ±20 V (5 kΩ), 5 Vrms (50 Ω) External clock sensitivity 200 mVpp (minimum required signal swing) External clock level software programmable ±5 V in steps of 1mV External clock edge rising edge used External reference clock input duty cycle 45% - 55% Clock output electrical specification Available via Multi Purpose output X0. Refer to „Multi Purpose I/O lines“ section. Synchronization clock multiplier „N“ for software programmable N being a multiplier (1, 2, 3, 4, 5, ... Max) of the card with the currently slowest sampling clock. different clocks on synchronized cards The card maximum (see „Clock Limitations and Bandwidth“ table below) must not be exceeded. Channel to channel skew on one card < 200 ps (typical) Skew between star-hub synchronized cards TBD Clock Limitations M2p.653x M2p.656x DNx.653-xx DNx.656-xx M2p.654x M2p.657x DNx.654-xx DNx.657-xx max internal clock (non-synchronized cards) 40 MS/s 125 MS/s min internal clock (non-synchronized cards) 1 kS/s 1 kS/s max internal clock (cards synchronized via star-hub) 40 MS/s 125 MS/s min internal clock (cards synchronized via star-hub) 128 kS/s 128 kS/s max direct external clock 40 MS/s 125 MS/s min direct external clock DC DC min direct external clock LOW time 4 ns 4 ns min direct external clock HIGH time 4 ns 4 ns

Bandwidth and Filters Filter - 3dB bandwidth Filter characteristic Analog bandwidth does not include Sinc response of DAC Filter 0 70 MHz third-order Butterworth Filter 1 20 MHz fifth-order Butterworth Filter 2 5 MHz fourth-order Bessel Filter 3 1 MHz fourth-order Bessel Dynamic Parameters M2p.653x/DNx.653-xx Test - Samplerate 40 MS/s 40 MS/s Output Frequency 800 kHz 4 MHz Output Level in 50 Ω ±900mV ±3000mV ±900mV ±3000mV Used Filter 1 MHz 5 MHz NSD (typ) -142 dBm/Hz -132 dBm/Hz -142 dBm/Hz -132 dBm/Hz SNR (typ) 90.7 dB 91.1 dB 83.7 dB 84.1 dB THD (typ) -74.0 dB -74.0 dB -70.5 dB -70.5 dB SINAD (typ) 73.9 dB 73.9 dB 69.8 dB 69.8 dB SFDR (typ), excl harm. 97.0 dB 95.0 dB 88.0 dB 88.0 dB ENOB (SINAD) 12.0 12.0 11.3 11.3 ENOB (SNR) 14.7 14.8 13.5 13.6 M2p.654x/DNx.654-xx Test - Samplerate 40 MS/s 40 MS/s Output Frequency 800 kHz 4 MHz Output Level in 50 Ω ±900mV ±6000mV ±900mV ±6000mV Used Filter 1 MHz 5 MHz NSD (typ) -138 dBm/Hz -129 dBm/Hz -142 dBm/Hz -126 dBm/Hz SNR (typ) 86.7 dB 88.1 dB 83.7 dB 84.2 dB THD (typ) -74.0 dB -74.0 dB -74.0 dB -74.0 dB SINAD (typ) 73.8 dB 73.8 dB 73.6 dB 73.6 dB SFDR (typ), excl harm. ENOB (SINAD) 12.0 12.0 11.9 11.9 ENOB (SNR) 14.1 14.3 13.6 13.7 M2p.656x/DNx.656-xx Test - Samplerate 125 MS/s 125 MS/s 125 MS/s Output Frequency 800 kHz 4 MHz 16 MHz Used Filter 1 MHz 5 MHz 20 MHz Output Level in 50 Ω ±900mV ±3000mV ±900mV ±3000mV ±900mV ±3000mV NSD (typ) -142 dBm/Hz -132 dBm/Hz -142 dBm/Hz -132 dBm/Hz -142 dBm/Hz -132 dBm/Hz SNR (typ) 90.7 dB 91.1 dB 83.7 dB 84.1 dB 77.7 dB 78.1 dB THD (typ) -74.0 dB -74.0 dB -70.5 dB -70.5 dB -66.0 dB -61.9 dB SINAD (typ) 73.9 dB 73.9 dB 69.8 dB 69.8 dB 65.7 dB 60.9 dB SFDR (typ), excl harm. 97.0 dB 95.0 dB 88.0 dB 88.0 dB 90.0 dB 89.0 dB ENOB (SINAD) 12.0 12.0 11.3 11.3 10.6 9.8 ENOB (SNR) 14.7 14.8 13.5 13.6 12.5 12.6 M2p.657x/DNx.657-xx Test - Samplerate 125 MS/s 125 MS/s 125 MS/s Output Frequency 800 kHz 4 MHz 16 MHz Used Filter 1 MHz 5 MHz 20 MHz Output Level in 50 Ω ±900mV ±6000mV ±900mV ±6000mV ±900mV ±6000mV NSD (typ) -138 dBm/Hz -129 dBm/Hz -142 dBm/Hz -126 dBm/Hz -142 dBm/Hz -127 dBm/Hz SNR (typ) 86.7 dB 88.1 dB 83.7 dB 84.2 dB 77.7 dB 79.1 dB THD (typ) -74.0 dB -74.0 dB -74.0 dB -74.0 dB -70.5 dB -63.1 dB SINAD (typ) 73.8 dB 73.8 dB 73.6 dB 73.6 dB 69.7 dB 63.0 dB SFDR (typ), excl harm. ENOB (SINAD) 12.0 12.0 11.9 11.9 11.3 10.2 ENOB (SNR) 14.1 14.3 13.6 13.7 12.6 12.8 THD 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.

DN6 specific Technical Data Environmental and Physical Details DN6.xxx Dimension of Chassis without connectors or bumpers L x W x H 464 mm x 431 mm x 131 mm Dimension of Chassis with 19“ rack mount option L x W x H 464 mm x TBD mm x 131 mm (3U height) Weight (3 internal acquisition/generation modules) 12.1 kg, with rack mount kit: TBD kg Weight (4 internal acquisition/generation modules) 12.5 kg, with rack mount kit: TBD kg Weight (5 internal acquisition/generation modules) 12.9 kg, with rack mount kit: TBD kg Weight (6 internal acquisition/generation modules) 13.4 kg, with rack mount kit: TBD kg Warm up time 10 minutes Operating temperature 0°C to 40°C Storage temperature -10°C to 70°C Humidity 10% to 90% Dimension of packing (single DN6) L x W x H 580 mm x 580 mm x 280 mm Volume weight of Packing (single DN6) 19.0 kgs Power Consumption 230 VAC 24 channel versions, standard memory TBD TBD 32 channel versions, standard memory TBD TBD 40 channel versions, standard memory TBD TBD 48 channel versions, standard memory TBD TBD MTBF MTBF TBD hours Block diagram of generatorNETBOX DN6 • The number of maximum channels and internal AWG modules and existance of a synchronization Star-Hub is model dependent.

Block diagram of generatorNETBOX module DN6.65x

Order Information The digitizerNETBOX is equipped with a large internal memory for data storage and supports standard acquisition (Scope), FIFO acquisition (streaming), Multiple Recording, Gated Sampling, ABA mode and Timestamps. Operating system drivers for Windows/Linux 32 bit and 64 bit, drivers and examples for C/C++, IVI (Scope and Digitizer class), LabVIEW (Windows), MATLAB (Windows and Linux), .NET, Delphi, Java, Python and a Professional license of the oscilloscope software SBench 6 are included. The system is delivered with a connection cable meeting your countries power connection. Additional power connections with other standards are available as option. digitizerNETBOX DN6 - Ethernet/LXI Interface Order no. Resolution Output Channels Memory Output@50Ω Output@1MΩ DN6.653-24 16 Bit 24 channels 40 MS/s 3 x 512 MSamples ±3V ±6V DN6.653-32 16 Bit 32 channels 40 MS/s 4 x 512 MSamples ±3V ±6V DN6.653-40 16 Bit 40 channels 40 MS/s 5 x 512 MSamples ±3V ±6V DN6.653-48 16 Bit 48 channels 40 MS/s 6 x 512 MSamples ±3V ±6V DN6.656-24 16 Bit 12 channels 125 MS/s 3 x 512 MSamples ±3V ±6V 24 channels 80 MS/s DN6.656-32 16 Bit 16 channels 125 MS/s 4 x 512 MSamples ±3V ±6V 32 channels 80 MS/s DN6.656-40 16 Bit 20 channels 125 MS/s 5 x 512 MSamples ±3V ±6V 40 channels 80 MS/s DN6.656-48 16 Bit 24 channels 125 MS/s 6 x 512 MSamples ±3V ±6V 48 channels 80 MS/s Options Order no. Option DN6.xxx-Rack 19“ rack mounting set for self mounting DN6.xxx-Emb Extension to Embedded Server: CPU, more memory, SSD. Access via remote Linuxs secure shell (ssh) DN6.xxx-BTPWR Boot on Power On: the digitizerNETBOX/generatorNETBOX automatically boots if power is switched on. BNC Cables The standard adapter cables are based on RG174 cables and have a nominal attenuation of 0.3 dB/m at 100 MHz. for Connections Connection Length to SMA male to SMA female to BNC male to SMB female All BNC male 80 cm Cab-9m-3mA-80 Cab-9m-3fA-80 Cab-9m-9m-80 Cab-9m-3f-80 All BNC male 200 cm Cab-9m-3mA-200 Cab-9m-3fA-200 Cab-9m-9m-200 Cab-9m-3f-200 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.