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Connectivity
Use USB 2.0 interface (standard), 100BaseTX /10BaseT (option), or GPIB (available using a National Instruments NI PCMCIA-GPIB card) to remotely control the DL9000 and to transfer waveform data from the scope. The industry standard USBTMC-USB488 with USB 2.0 interface offers data transfer rates that exceed typical GPIB data transfer rates.
For data storage, you can use a PC card drive (available in both front and rear panels) or USB interface. These interfaces support media such as CompactFlash, PC Card type II HDD, and USB memory
GPIB interface
(Two PC card interfaces are standard. However, a NI PCMCIA- GPIB card is required for communication. You can use the front or back panel PC Card interfaces for this purpose.)
PC Card/USB interfaces
Use popular, widely available, large capacity media such as CompactFlash or USB HDD to save and transfer waveform data captured with the DL9000.
A USB mouse and/or keyboard can be used to facilitate operation of the unit. The front USB port can also be used to connect to a USB printer.
Web Services
Turn Your DL9000 into a Web Server
The DL9000 can function as an independent Web server. Connect to your DL750P directly using Internet Explorer, and access a variety of services.
FTP
Easily copy and paste files to and from a PC from the internal flash memory drive and other internal storage media. You don't have to use a separate program to transfer the data.
Ethernet (optional)
Connecting to a PC
Web Server With an Ethenet connection, you can perform various functions using Internet Explorer.
Web Server and FTP Server
The DL9000 series have a variety of server functions that let you perform remote control or download waveform data and screen images onto a PC. You can also access the DL9000 through standard PC software like Internet Explorer and Windows Explorer.
Just as for RS232 and GB-IB, you can write your own custom programs in Visual C++ 6.0 or Visual Basic 6.0 to control the DL9000 through a USB interface.
PC communications are made easy with the Waveform Viewer and Wirepullersoftware programs.
Accessories
PBA2500 2.5 GHz
active probe
Use this 10:1 active probe with the DL9000 to realize system measurements up to 1.5 GHz BW.
Bandwidth:
DC to 2.5 GHz (-3 dB)
Attenuation: 10:1 (±2%)
Input resistance:
100 kΩ (±2%)
Input capacitance: approx 0.9 pF (typ.)
Dynamic range: ±7 V
Max. input voltage:
±25 V DC + AC peak
Offset voltage: ±10 V
PBL5000 5 GHz
low capacitance probe
This 10:1 and 20:1 (selectable) passive probe is used with the 50 ohm input setting on the DL9000. The change in attenuation is realized by changing resistance on the tip of the probe.
Bandwidth: DC to 5 GHz (-3 dB)
Attenuation: 10:1 or 20:1 (±2%)
Input resistance: 450 Ω or 950 Ω (±2%)
Input capacitance: approx 0.25 pF
(typ. 450 Ω),
0.4 pF
(typ. 950 Ω)
Max. input voltage: 20 Vrms
PB500 500 MHz
passive probe
This probe can be used for general purpose day-to-day measurements up to 500 MHz BW. The DL9000 series comes standard with foure PB500 probes.
Attenuation: 10:1 (±2%)(When used with the DL9000)
Input resistance:
10 MΩ ±2%
Input capacitance: approx 14 pF (typ.) (When used with the DL9000)
Max. Input range:
±600 V DC + AC peak
701975 50 ohm
DC block
This DC block can be used to remove the DC component from an incoming signal. Use this block if you want to remove bias voltage from reaching the PBL5000 probe.
701920 500 MHz
differential probe
For differential signal measurements. Order the DL9000 with the /P2 option to directly power the probe off the scope.
Attenuation:
10:1 (±3%)
Input
resistance
(typ.)100 kΩ
Input capacitance
(typ.) 2.5 pF
Max. allowable
differential voltage:
±12 V DC + AC peak
Max. common mode
voltage:
±30 V DC + AC peak
701932 100MHz
current probe
Clamp-type current probe. Order the DL9000 with the /P2 option to directly power the probe off the scope.
Bandwidth: DC to 100 MHz (-3 dB)
Max. continuous input range: 30 Arms, 50 A peak
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- 4 input channels
- Analog BW
500 MHz (DL9040/DL9040L)
1 GHz (DL9140/DL9140L)
1.5 GHz (DL9240/DL9240L)
- Max. sample rate
5 GS/s (2 channels) 2.5 GS/s(4 channels) (DL9140/DL9140L)
10 GS/s (2 channels) 5 GS/s (4 channels) (DL9240/DL9240L)
- Max. record length
2.5 M word/channel (DL9140/DL9240)
6.25 M word/channel (DL9140L/DL9240L)
- Fast acquisition rate
Max. 2.5 M waveforms/sec/ch
- I2C and SPI Bus Analyzer (optional)
- History memory function
Review & analyze up to 2,000 of the most recent waveforms after the acquisition is stopped
- Compact and light weight
18 cm (7.1") depth, 6.5 kg (14.5 lbs.)
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View Flash DEMO |
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The DL9000 signalXplorer is Yokogawa's 10(X)th generation digital oscilloscope. It allows users to select the most appropriate memory setting for a given measurement and then acquires and displays long and short memory records quickly, saving the waveforms to its segmented memory. Advanced memory handling ensures that you get all the benefits of a long memory scope regardless of the record size you allocate for each acquisition. This is made possible by the state-of-the-art ADSE (advanced data stream engine) ASIC.
see our advert in Electrical Line Magazine |
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- Affordable performance for 1 GHz / 1.5 GHz bandwidth measurements
- The standard DL9000 series is equipped with 2.5 M word/ch record length, dot density display technology and a wide variety of analysis and trigger functions. For full 1 GHz/1.5 GHz BW measurements, optional 2.5 GHz active probes are available. This makes the DL9000 the most affordable 1 GHz/1.5 GHz measurement system available today.
- Advanced display technology
(Dot density display) Mask testing
- DL9000 Trigger types
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- History memory with fast signal acquisition
Fast signal acquisition helps you avoid missing anomalies. However, simple superimposed waveform displays only tell whether or not an anomaly occurred. Such displays do not provide information about when the anomaly occurred, what events occurred before the anomaly, nor what happened after the anomaly. The DL9000's History memory function allows you to view and analyze up to 2000 previously acquired waveforms, even after the acquisition stops. This offers unparalleled insight into waveform behavior and makes troubleshooting easier.
- History memory advantage #1:
Correlate events from multiple channels
(Up to 2000 waveforms can be saved in history memory)
- History memory advantage #2: Determine sequence of events
History memory captures and saves waveforms before and after the anomaly; thus providing insight into the cause and effect of the anomaly.
- History Replay
When acquisition stops and there are more than two acquisitions in memory, the HISTORY key is illuminated. At that time, you can use the rotary knob to view every single acquisition in memory, one-by-one, and look for an anomaly. The new History Replay function allows you to play back the waveforms in memory in the same way you play back video on a DVR.
- History memory - access method:
- Reviewing each acquisition one by one
- Playing back history memory continuously
- Security for confidential tests
The DL9000 series can be configured without the optional internal HDD. For units without the HDD, it is both easy and fast to securely erase all the data in the unit. Therefore, you do not have to worry about your confidential test results being transferred to a different location, along with the unit.
- Flexible acqusitions
The DL9000 signalXplorer is Yokogawa's 10(X)th generation digital oscilloscope. It allows users to select the most appropriate memory setting for a given measurement and then acquires and displays long and short memory records quickly, saving the waveforms to its segmented memory. Advanced memory handling ensures that you get all the benefits of a long memory scope regardless of the record size you allocate for each acquisition. This is made possible by the state-of-the-art ADSE (advanced data stream engine) ASIC.
- ADSE offers two fast signal acquisition modes
- N Single Mode
When you need to observe closely-spaced waveform events consecutively, it is important to minimize the dead time between captures. The 'N single' mode on the DL9000 captures up to 1,600 waveforms on each of 4 channels with as little as 400 ns of dead time between acquisitions. In the 500 ps/div range, this corresponds to an effective acquisition rate of 2.5 M waveforms/sec/ch.
- New ACCUM (accumulation) mode
When observing long-term repetitive waveform events, the ACCUM function offers a fast repetitive signal acquisition rate of up to 25 k waveforms/sec/ch (on 4 channels simultaneously) while retaining up to 2,000 acquisitions in memory.
Whether you use N single or the ACCUM function, previously acquired waveforms are stored in memory and can be accessed using the History Function.
- Search Function
Both Zoom search and History search functions are available in the signalXplorer. Zoom search locates an area of interest in a single acquisition. History search locates any acquisitions in history memory that meet user-selected criteria
- Dot Density Display
The intensity of individual display pixels are varied depending on how often a signal illuminates each pixel. Even for single shot acquisitions, Dot Density Display provides visual information about the S/N ratio of a signal. For repetitive signal acquisitions, this feature offers additional insight into the frequency of occurrence of portions of a signal over time. In short, Dot Density Display technology offers analog oscilloscope-like waveform representations on a digital scope
- A small footprint means more room on your bench for the DUT
- 1 GHz oscilloscope depth comparison
The DL9000 is only 35 cm wide and 18 cm deep so it does not take up all your valuable bench space. And it weighs only 6.5 kg so it is easy to move from one bench to another.
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- Enhanced Analysis & Math
- Histogram displays
Gain new perspectives on your waveforms by using time and voltage histograms. For example, signal jitter can be shown using a time histogram, and noise on DC signals can be visualized using a voltage histogram.
- Statistics
Use the statistics functions to generate statistical information (max, min, avg, std dev, etc.) about waveform parameters. Continuous statistics (running statistics on selected parameters during acquisition), Cycle statistics (statistical information about a waveform on a cycle-by-cycle basis) and History statistics (statistics on waveforms captured in history memory) are all available.
- FFT
The DL9000 series can calculate FFT waveforms using up to 250 k points. To scale the results, you can specify the center frequency and the frequency span, just like you would do with a spectrum analyzer.
- Trend displays
Track long-term waveform parameter trends using the trend display. The Trend display can be used to visualize fluctuations of a selected parameter.
- Mask Testing
With free Mask Editor Software, you can define a mask and then test to see whether or not the measured signal falls in/out of the mask. Masks for a variety of communication signals can be defined.
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- Waveform math
Define up to 8 math traces. Functions include: filtering, +, -, x, Integration, Edge Count and Rotary Count. Basic arithmetic functions are performed using the ADSE (hardware) and results are displayed in real time.
- Real-time analog/digital filtering
200 MHz and 20 MHz analog low pass filters and 8 MHz, 4 MHz, 2 MHz, 1 MHz, 500 kHz, 250 kHz, 125 kHz, 62.5 kHz, 32 kHz, 16 kHz and 8 kHz digital low pass filters are available for real-time filtering. These filters can be applied to live signals without slowing down the signal acquisition rate. Additional types of digital filtering are available using the math function.
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Additional details about Yokogawa’s software tools and information for downloading trial versions of the software can be found at:
http://www.yokogawa.com/tm/tm-softdownload.htm |
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Xviewer (sold separately) |
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Xviewer runs on a PC and can be used for viewing saved waveform data, converting binary data to ASCII, and for calculating automatic waveform parameters. With the Math edition of Xviewer you can calculate up to 10 math waveforms based on waveform data and do FFT calculations using up to 2 million points.
Click here to download |
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MATLAB Control Tool Kit (sold separately) |
The MATLAB tool kit enables DL series oscilloscopes to easily interface with MATLAB. The software can be used to control supported DL series instruments from MATLAB or to transfer data from DL series instruments to MATLAB via GPIB, USB or Ethernet.
Click here to download |
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DL Series Library (freeware) |
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This API lets you control or receive waveform data from the DL9000 remotely. The API is available as a DLL and can be called from your program.
Click here to download |
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Mask Pattern Editor (freeware) |
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This software program is used to create mask patterns that are used on the DL9000. The mask pattern created using this program can be loaded into the DL9000 via a PC card or USB memory and used for mask tests, GO/NO-GO judgements, and history search.
Click here to download |
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Wirepuller |
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Wirepuller displays an image of the DL9000 Series front panel on your PC for monitoring waveform signals.
You control the DL9000 Series by simply using your PC's mouse and keyboard to perform actions on the displayed front panel.
Interface: USB/GP-IB/Ethernet
Click here to download |
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Built-in Printer (/B5) |
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This built-in thermal paper printer provides a convenient way to print out what is shown on the DL9000’s display.
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Probe Power (/P2) |
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These ports supply power to the following current probes (701932, 701933) and the following differential probes (701920, 701921, 701922, 700924, 700925)
Note: You do not need this option to power the 2.5 GHz active probe (PBA2500). |
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100 BaseTX/ 10 BaseT Ethernet (/C10) |
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100 BaseTX/ 10 BaseT Ethernet (/C10)
100 BaseTX/ 10 BaseT Ethernet + internal HDD (/C8)
Network file server/client functions and network printing are supported through Microsoft network file sharing. The SMTP client allows you to send e-mail from the unit. (/C8, /C10)The /C8 option includes an internal 30 GB HDD which can be used to store waveforms and setup files. |
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I2C and SPI Bus Analyzer (/F5) |
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This option enables, analysis, and search on I2C and SPI
serial data bus signals. Observing the physical signals of these buses allows you to more effectively separate hardware related problems from software related problems.
(I2C and SPI triggers are standard) |
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Downloads:
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