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dsa71604 user manualAvailable 6:00 AM - 4:30 PM PST. Service ManualBy downloading manuals from Tektronix' website, you agree to the following terms and conditions: Manuals for currently supported products may not be reproduced for distribution to others unless specifically authorized in writing by Tektronix, Inc. Thus, different versions of a manual may exist for any given product. Care should be taken to ensure that one obtains the proper manual version for a specific product serial number. Tektronix hereby grants permission and license for others to reproduce and distribute copies of any Tektronix measurement product manual, including user manuals, operator's manuals, service manuals, and the like, that (a) have a Tektronix Part Number and (b) are for a measurement product that is no longer supported by Tektronix. Thus, different versions of a manual may exist for any given product. Care should be taken to ensure that one obtains the proper manual version for a specific product serial number. Quick Start User ManualBy downloading manuals from Tektronix' website, you agree to the following terms and conditions: Manuals for currently supported products may not be reproduced for distribution to others unless specifically authorized in writing by Tektronix, Inc. Thus, different versions of a manual may exist for any given product. Measure voltage or current signals over time in an electronic circuit or component to The DSA71604 is a 16 GHz, 4 channel digital oscilloscope from Tektronix. DPO7000, DPO70000 and DSA70000 Series Service Manual DSA71604 BASE exception.Features include variable articulation of probe tip. Download File. By downloading, you agree to the terms and conditions of the Manuals Download Agreement. Louis Rams. For the best experience on our site, be sure to turn on Javascript in your browser. Measure voltage or current signals over time in an electronic circuit or component to display amplitude, frequency and rise times, etc.http://www.bearlakecondo.net/userfiles/8202-e4b-sales-manual.xml

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Applications include troubleshooting, production test, and design. The specialized DSA71604 provides a complete and dedicated solution to address the challenges of high-speed serial designs. Allows connection or disconnection of USB keyboard, mouse or storage device while oscilloscope is on USB2 USB 2.0 Compliance Test Software only Datasheets Tektronix DPO7000, DSA7000 Series Manuals Tektronix MSO7000C, DSA7000B-C, DPO7000B-C, DPO7000, MSO5000, DPO5000 Series User Manual Looking for other manuals. Search all of our available manuals here. About Us Terms and Conditions Privacy and Cookie Policy Contact Us Educational Discounts ValueTronics New and Used Test Equipment, All Rights Reserved. The RSAVu software operates the same way as the instrument software.The software emulates the RSA3408B spectrum analyzer software option suite, which allows the user to perform the same analysis on a PC that one can perform on an RSA3408B spectrum analyzer.The maximum file size supported for a.tiq file is 256 MB.Users can programmatically load RSA data files and extract demodulated parameters using their test software to minimize time required for conformance and stress testing.Wide Choices of Low-pass Filters, High-pass Filters, Band-pass Filters, and De-emphasis Settings. Choose from a Standard Certificated Service or an internationally recognised UKAS accredited calibration. Visit the calibration service page for more details. By using our website and services, you expressly agree to the placement of our performance, functionality and advertising cookies. Please see our Privacy Policy for more information. Update your browser for more security, comfort and the best experience for this site. Try Findchips PRO. Use our IVI Class Drivers in conjunction with this driver to create interchangeable instrument-control applications.Notice that this is aIf you have not downloaded NI Package Manager, download it now. To download the required software, visit Drivers and Updates.http://cslcedu.com/userfiles/8202-e4b-manual.xml In order to help us prioritize future development, please select the primary interface you intend to use with this driver. The item may have some signs of cosmetic wear, but is fully operational and functions as intended. This item may be a floor model or store return that has been used. See the seller’s listing for full details and description of any imperfections. Condition: goodAuto Setup instantly sends meaningful waveforms. Pressing AUTOSET automatically adjusts the horizo. Contact Seller for Price Darmstadt, Germany Click to Contact Seller Used Tektronix TDS7254 Digital Oscilloscope in Mendon, MA Manufacturer: Tektronix The TDS7000 Series' superior measurement fidelity, analysis, and uncompromised usability combine to simplify and speed the design of high-speed, complex systems. This family offers a superior solution to the chal. Yes No Please tell us more so that we can improve our website: How can we get in touch with you? (optional) Send Feedback Thank you for making Machinio better. Your feedback is greatly appreciated. Building on our history of market-leading innovations in prob ing, After T riMode (P75TLRST): 1 Probe for Differe ntial, Singl e Ended, and Common Mode, with only 1 setup required.Improved productivity is achieved by reducing setup time. One setup can be used to make the three different types of measurements all with the press of a but ton. The TriMode Probe architecture for the P7500 Series probes continues the T ektronix tradition of high-bandwidth and low-DUT loading while providing improved connectivity and va lue. 2 www.tektronix.com The multipoint connectivity solutions of the P7500 Series include: Tr i M o d e P e r f o rmance Solder Tip The highe st-performance solder tip. Up to 25 GHz bandwidth. T riMode Lon g-reach Solder Tip A high performance solder tip with al o n gr e ach and very small, low-pro.T riMode R esistor Solder Tip High-performance solder tip with easy-to-solder tip resistors. Up to 18 GHz bandwidth.http://superbia.lgbt/flotaganis/1649493633 T riMode Exten ded-resistor Solder Tip Medium-performance solder tip with long easy-to-solder tip resistors. Up to 7 GHz bandwidth. www.tektronix.com 3 Up to 4 GHz bandwidth. Damped Wire Ti p Low-cost solder tips ideal for high-d ensity probing. Up to 8 GHz bandwidth. Precision Differential Prob ing Module High-performance handheld probing module. Up to 18 GHz b andwidth. Handheld and ? xtured probing needs are met using the o ptional Precision Differential Probing Module (P75PDPM). Its small precision tapere d tips, variable articulation of the probe tip, and quick-adjusting variable tip spacing provi des the needed.Thes e precision connectivity tools enable you to access multiple signals on anything from convenient test p ads to hard-to-reach, high-density circuitry. 4 www.tektronix.com The innovative new T ektronix differential architecture, coupled with the superior electrical performance of IBM SiGe T echnology, provides the bandwidth a nd.In addition to industry-leading service and support, this product c omes backed by a one-year warranty as standard.All Include: One-year warranty, plus see Standard Accessories table. Service Options Option Descripton CA1 Single Calibra tion or Functional Ve ri.All rights reserved. T e ktroni x products are covered by U.S. and foreign patents, issued an d pending. Information i n this publicat ion supersedes that in all previously publish ed material. Speci ? ca tion and pri ce change privileges r eserved. TEKTRONIX and TEK are registered trademar ks of Te k t r o n i x, Inc. Product(s) compl ies with IEEE Standard 488. 1-1987, RS-232-C, an d with T e ktronix Standard Codes and Formats. www.tektronix.com. CSA7000 series. The standard mask can be copied to a user mask and thenIf the Oscilloscope does not have the GPIB controller, Wavestar running on it willRefer to your userIf your oscilloscope does not have this ability, you canWith most operating.https://connylahnstein.com/images/california-traffic-school-manual.pdf Much More Than A Logic Analyzer AT-LA500 instrument is part of the Active Technologies instrument series called “hardware platforms”. The main advantage of those instruments is their FPGA based architecture that provides them with the remote hardware reconfiguration capability. This makes it possible to modify, with just a software update, the instrument hardware in order to improve it, to add it new features or to easily make customizations. Thanks to this technology the AT-LA500 integrates much more than standard logic analyzer functionalities. Connect your oscilloscope to AT-LA500 to make a unique Mixed Signal Tester. User friendly software permits to use advanced logic analyzer features without buttons, knobs and touch screen on the instrument; USB 2.0 interface transfers the acquired data to the PC within seconds. In mixed signal tests some additional features are required beyond bandwidth, sample rate and memory depth: Channel count Expandability Trigger levels Probe features Analogue-digital synchronization Many good oscilloscopes or mixed signal oscilloscopes are available at a very effective price. But as good are the performances of the analogue part as poor are those of the digital part which usually is not adequate for professional tests. AT-LA500 is a professional logic analyzer that can be tightly integrated with a standard oscilloscope providing the best mixed signal solution both in term of performance and price. New MSO Capability FREE on your Next DPO7000 Series Oscilloscope Tektronix partnering with Active Technologies in Italy, now offer an integrated high performance Mixed Signal capability for the DPO7000 series Oscilloscopes Active Technologies, AT-LA500, USB based logic analyzers, have been customized to work with the DPO7000 series Oscilloscope range. This customization provides a integrated capability for the Windows performance MSO market.https://www.saenger-ohg.de/wp-content/plugins/formcraft/file-upload/server/content/files/1629f7a6a34465---csi-9830-manual.pdf Synchronization AT-LA500 provides a dedicated expansion bus, called AT-XSS, for expandability and synchronization with external instruments (i.e. oscilloscopes). The synchronization is bidirectional so that the oscilloscope and the logic analyzer can be in turn the trigger master. Only two BNC cable must be connected between the two instruments to make the new mixed signal tester. Mixed signal waveform window The integration is also powered by the software interface that hides all the communication details between the AT-LA500 and the oscilloscope. The system configuration interface is very intuitive but powerful at the same time. Debugging digital hardware can be a difficult and long operation because new effects caused by fast edges like logic errors, crosstalk, ground bounce and power distribution artifacts can occur. The GigaView technology provides a 2ns timing resolution with up to 4 MSamples depth simultaneously with a 666 ps high resolution timing within the same acquisition and using the same probes. It is like performing two analysis in one: a deep timing analysis and an additional high-resolution timing analysis. Glitches Glithches are usually very narrow pulses that can be very difficult to detect, capture and hard to resolve. Their effect are often unpredictable and they can be the first sign of device faults like driver errors, timing violations and crosstalk. AT-LA500 deep timing signal waveform ( 2ns resolution and up to 4 MSamples memory depth) can examine all the signal lines of the bus at once and look for events or faults; after a particular event, like a glitch, has been detected, the GigaView waveforms can display all the channels in high resolution (666 ps) with 1024 samples depth per channel, providing the way to examine the event in detail. GigaView high-resolution timing window is able to reveal glitches and to measure their duration with high accuracy.www.fruko-schulz.com/upload/files/bt-hub-phone-manual.pdf Timing Margin Verification 666 ps resolution on all channels with a maximum skew of 666 ps from channel to channel, allows designers to move from simply troubleshooting apparent problems to actually verifying the timing margins of their designs. Sample points can be moved in 666 ps increments to precisely determine setup-and-hold windows and examine the behavior of clocks, data and address lines with respect to each other, and asynchronous inputs. Digital Pattern Generator-Sampler AT-LA500 can be configured to work as a powerful pattern generator-sampler. In this working mode AT-LA500 provides the capability to emulate standard serial or parallel bus transactions or custom digital interfaces for system or device debugging and characterization. The execution flow of the edited waveforms can be easily defined with a dedicated sequencer editor form. Protocol Analyzer Thanks to a dedicated hardware the AT-LA500 serial protocol analyzer provides the most advanced triggering capabilities on the market. A graphical user interface provides easy instrument setup and data analysis in graphical and tabular representations. Command interpretation is provided in both representation as well with cross probing features that allow to detect critical events very easily. Supported protocols: RS 232 I2C SPI Microwire 485 422 UART Accessories Probes Active Technologies offers a wide range of probing options to support different measurement needs. Number of inputs 18 in two banks of 9. Input capacitance Input resistance 22k. The BNC board provides a simple way to connect your oscilloscope with AT-LA500. BNC cables are not included. Download Docs Brochure AT-LA500. Brochure AT-LA500 Mixed Signal. Brochure AT-LA500 Digital Pattern Generator. Brochure AT-LA500 DPO7000. Brochure AT-LA500 Digital Serial Protocol Analyzer. Specs AT-LA500 ? User Manual AT-LA500. If you continue to use this site we will assume that you accept it. Ok Read more Scroll to top.https://www.enviedecrire.com/wp-content/plugins/formcraft/file-upload/server/content/files/1629f7a7dce88d---csi-9330-manual.pdf The unique schemes of the proposed MMWoF are the wavelength-locked colorless laser diode (CLD) modulator, the mutually incoherent optical carrier for heterodyne MMW generation, and the square-law power envelope detection at receiving end. By directly encoding the single-mode with the CLD modulator, the single-carrier modulated QAM-OFDM data is achieved to release the RF power fading after fiber transmission. The mutually incoherent laser beating enables the optical heterodyne MMW generation with two independent optical carriers, which provides the advantages of local-oscillator-free operation and rules out the requirement of dual-mode optical carrier delivery from central office. At the wireless receiving end, the received QAM-OFDM data is self-down-converted to the baseband by employing the square-law power envelope detection. This eliminates the requirement of local oscillator and rules out the influence of the MMW carrier frequency fluctuation between two mutually incoherent lasers (used at central office and remote node), which effectively provides the MMW carrier immunity against the down-conversion instability caused by clock jitter or carrier incoherence.Unfortunately, such an architecture suffers from the construction cost with local oscillator and related MMW components. The photomixing is a simple and cost-effective technique for MMW generation, which uses the dual-mode optical carrier to transmit the data from CO and employs the optical heterodyne for optical-to-MMW carrier conversion after receiving at remote node to simplify the infrastructure of the MMW BSs 17, 18, 19. To synthesize the typical dual-mode optical carrier for the optical heterodyne MMWoF systems, the central-carrier suppressed double-sideband (CCS-DSB) optical carrier with high coherence feature is usually employed as representative candidate, which can be generated by externally modulating a continuous-wave (CW) laser with a nully-biased Mach-Zehnder modulator (MZM) 20, 21.https://www.uppld.org/wp-content/plugins/formcraft/file-upload/server/content/files/1629f7a800edb5---Csi-85t-manual.pdf The data-stream can be encoded onto the dual-mode optical carrier via the external modulation with an additional optical modulator 22, 23; however, such an architecture relies on electro-optic double-sideband data modulation and suffers from chromatic dispersion induced power fading after fiber transmission 24, 25. This severely limits the allowable transmission distance of the MMWoF even with single-mode fiber (SMF) 14. Technically, the RF power fading induced modulation spectral notch can be cost-ineffectively released by using optical single-sideband modulation with dual-electrode MZM 26, 27, 28, 29. Alternatively, the directly modulated laser with dual wavelengths can also be considered to provide the either single-mode or dual-mode optical carrier modulation with enhanced modulation bandwidth and suppressed intensity noise under injection 30, 31. Particularly, similar technology treats the slave laser as both modulator and amplifier that has ever been reported. For the MMWoF with embedding dual carriers, the wavelength-locking a single-mode slave laser with the dual-mode master has also emerged to achieve optically single-sideband modulation to entirely release the induced RF power fading effect; 32 however, the low injection efficiency and narrow wavelength tolerance of conventional laser diode restricts its applicability for multi-channel universal wavelength-division-multiplexed passive optical network (DWDM-PON) applications. In view of versatile approaches for dual wavelength applications, directly combining two independent CW lasers is the simplest way to generate the mutually incoherent dual-mode optical carrier, as which can arbitrarily adjust its mode spacing and wavelength by detuning either one 33. Nevertheless, the currently proposed incoherent dual-mode carrier still requires an external modulator to encode the data.www.daisy-book.com/userfiles/files/bt-hub-phone-2_1-manual.pdf Besides, one serious drawback of this technology is that the mutual incoherence between two independent lasers also fluctuates the frequency of the beat MMW carrier after optical heterodyne detection at remote node. Such an approach suffers from the down-conversion instability to make it inappropriate for most MMWoF systems. More recently, the microwave power detector with the square-law power envelope detection function has been proposed to considerably release the frequency instability during down-converted mixing process, which allows the MMW signal self-converting down to the baseband without using local oscillator at remote node 12, 34. The MMW carrier is synthesized by remotely combining the down-stream single-carrier transmitted data with another independent single-mode carrier at the optical receiving end. The direct modulation of down-stream data is performed by using a wavelength-locked colorless laser diode (CLD) modulator, which allows the single-mode optical carrier to carry the quadrature amplitude modulation (QAM) and orthogonal frequency division multiplexing (OFDM) data. As the incoherence between two optical carriers from CO and remote node inevitably fluctuates the optically heterodyned MMW carrier frequency, it induces tremendous down-conversion frequency instability at wireless receiving end. This issue is released by employing the square-law power envelope detection technique, which makes the MMW central carrier and its carried QAM-OFDM data self-down-convert to baseband without disregarding the carrier frequency fluctuation. To flatten the signal-to-noise ratio (SNR) of the received QAM-OFDM data, the pre-emphasis technique is introduced before encoding onto the CLD modulator. The allowable modulation bandwidth of the optimized QAM-OFDM data is analyzed before and after 50-km SMF transmission. After remotely beating the mutually incoherent two-wavelength optical carriers at optical receiver, the MMW wireless transmission performances of the 3-m free-space transmitted QAM-OFDM data are examined, including the error vector magnitude (EVM), SNR and bit error rate (BER). To confirm the multi-channel DWDM flexibility, the allowable channel number availably offered by such a mutually incoherent dual-wavelength optical carriers for the MMWoF link is surveyed.To avoid such a noise variation originated from beating the free-running and coherence-independent carriers, the square-law power envelope detector is employed, which can self-down-convert the QAM-OFDM data from MMW band to the baseband without using microwave local-oscillator and rules out the down-conversion instability induced noise term.Based on such a relationship, the electrical power of the down-converted OFDM data can be effectively boosted by increasing the optical power of the localized TL at a fixed responsivity of the PD receiver. In the proposed concept, the localized TL is thus treated as the key light source to not only provide a remotely coherence-independent optical carrier but also amplify the receiving power of the down-converted OFDM data. Throughput characteristics of wavelength-locked CLD modulator and Encoding the 64-QAM OFDM Data via the wavelength-locked CLD modulator for optical down-stream transmission Externally seeding the CLD modulator with master not only controls the selected DWDM channel wavelength but also enlarges the modulation bandwidth with extremely low intensity noise during the QAM-OFDM data encoding. That is, either the large bias or the strong injection substantially up-shifts the relaxation oscillation frequency of the CLD modulator, which therefore sacrifices the low frequency energy to extend the broadband response. On the other hand, wavelength-locking the CLD modulator not only increases its relaxation oscillation frequency but also suppresses its relative intensity noise (RIN) 38. Figure 2 Output characteristics of wavelength-locked CLD and transmission performance of carried 64-QAM OFDM data at optical BtB transmission. ( a ) Optical spectra, ( b ) power-to-current responses, ( c ) frequency responses, and ( d ) RIN responses of CLD modulator with and without wavelength-locking. ( e ) BER and constellation plots. ( f ) SNR responses at different bias currents. ( g ) SNR responses with different frequency spacing deviated from the DC point. This is caused by either the saturation clipped or the roll-off declined throughput response of the CLD modulator, which degrades the SNR response of the QAM-OFDM data carried by OFDM subcarriers at high frequencies. By implementing the emphasis, the allowable bandwidth of the 64-QAM OFDM data carried by the wavelength-locked CLD modulator can also be enlarged as well. Figure 3 Transmission performance of 64-QAM OFDM data with and without pre-emphasis. ( a ) SNR responses and difference, and ( b ) constellation plots of 64-QAM OFDM data with and without pre-emphasis. ( c ) SNR responses and ( d ) constellation plots of the 64-QAM OFDM data at different modulation bandwidths after pre-emphasis. Note that both 8- and 9-GHz wideband QAM-OFDM data can pass the FEC criterion, whereas the 10-GHz wideband QAM-OFDM fails to be successfully decoded even with aforementioned processing. Even with the pre-emphasis for flattening the BtB transmitted SNR response, the long-reach SNR of the QAM-OFDM data still fails to meet the FEC criterion as the enhancement by pre-emphasis dose not overcome the power fading induced degradation on receiving power. Full size image To meet the FEC criterion, the allowable modulation bandwidth of the long-reach 50-km SMF transmitted QAM-OFDM data with the pre-emphasis has to be educed accordingly. Even with the pre-emphasis technology for flattening the SNR response, the QAM-OFDM data still requires more power to maintain its SNR during long-reach transmission. Besides, the slope of BER vs.As the injection locking mechanism forces the slave colorless laser diode to concurrently lock its wavelengths with two independent laser diodes, the relative frequency fluctuation between two master laser diodes still exists such that the optically heterodyned MMW carrier exhibits corresponding frequency variation. Even through the incoherent dual-mode optical carriers beat a broadband fluctuated and scanned MMW carrier, our work will demonstrate that the 60-GHz MMW carried QAM-OFDM data can be stably down-converted to the baseband with high immunity to the carrier frequency instability by using the power detector with the square-law power envelope detection. Figure 5 Carrier frequency fluctuation of 60-GHz MMW signal optically heterodyned from mutually incoherent and coherent dual-wavelength optical carriers. ( a ) Optical spectra, and ( b ) beat electrical spectra of the incoherent and coherent dual-wavelength laser sources for optical heterodyne of MMW central carriers. DWOC: dual-wavelength optical carriers. The related EVM slightly degrades from 12.3 to 11 after implementing the pre-emphasis. Therefore, the SNR degradation by the SMF propagation loss and the erbium-doped fiber amplifier (EDFA) noise is compensated by enlarging the gain of the EDFA. In particular, the proposed MMWoF reveals similar BER before and after 50-km SMF transmission. As long as the MMWoF link reserves sufficient optical receiving power for the QAM-OFDM data, the pre-emphasis can effectively flatten its SNR and optimize its BER to the same level. To approach the multi-channel DWDM applications, the allowable channel number of the mutually incoherent dual-mode optical carriers is surveyed. To apply the proposed MMWoF for long-reach SMF transmission, the output power of the wavelength-locked CLD modulator must be sufficiently boosted to overcome the attenuation and noise. Note that the BER obtained in the 1 st and 13 th channels are degraded as the locked wavelength of the CLD modulator has already approached the gain spectral edge of the CLD and EDFA such that insufficient power cannot support MMWoF transmission. Figure 8 Allowable channel number of 50-km SMF and 3-m wireless transmitted 32-QAM OFDM data carried by mutually incoherent dual-wavelength optical carriers. ( a ) Optical spectra of free-running CLD modulator and long-reach boost EDFA, ( b ) optical spectra of selectable dual-wavelength DWDM channels for the proposed MMWoF, and ( c ) BER performances of 32-QAM OFDM data carried by different channels of the mutually incoherent dual-wavelength optical carriers. Full size image During experiments, different modulation formats were encoded onto the optical baseband and the MMW passband across the different steps due to the limitation set for different carriers. At the back to back transmission, there is no dispersion effect and ASE noise from the optical amplifier. Among them, mixing the baseband data with a local oscillator for frequency up-conversion before modulating onto the LD at CO is the simplest way, which allows the MMW carrier that can be remotely obtained after optical receiving at BS 39. For confirmation, Kuri et al.To avoid the use of high-frequency mixer at the CO, optically generating the 60-GHz MMW carrier is proposed, which remotely beats the dual-mode optical carrier with optical heterodyne detection 17. Typically, the dual-mode optical carrier can be generated by employing a CCS-DSB optical carrier, which concurrently carries the baseband data by using either an external or a direct modulator. However, the dual-carrier modulation induces serious RF power fading effect caused by the chromatic dispersion to limit the SMF transmission distance. In 1999, Sotobayashi et al. To provide multi-MMW-band application, Hsueh et al. Table 1 Optically transmitting and receiving architectures for implementing the 60-GHz MMWOF link. Full size table To reduce the required local oscillator frequency by 2.5 times, Lin et al. used two dual-parallel MZMs to implement optical frequency multiplication for implementing the 60-GHz MMWoF link with the optical single-carrier modulation 28. To further enlarge the transmission capacity, Lin et al. Although the externally modulated method can deliver the high-quality dual-mode optical carrier to demonstrate the high-speed MMWoF system, it cannot be regarded as a cost-effective and simple solution as the additional data encoder is inevitably required. To avoid the use of the external modulation, Choi et al.To solve these problems, Ogusu et al.Therefore, the CLD modulator with weaker front-facet reflectance and longer cavity length is employed to provide higher injection efficiency for constructing the multi-channel MMWoF system 14. To completely avoid the use of the CCS-DSB master for cost-effective, Chen et al.However, the superposition of intensity noises for the master-to-slave wavelength-locked CLD inevitably degrades the carried data quality. On the other hand, Al-Dabbagh et al.To approach the optical single-carrier modulation, Zhang et al.To further lengthen the free-space transmission distance, Tsai et al.The QAM-OFDM data is directly encoded onto the wavelength-locked CLD modulator based single-mode optical carrier, which can entirely acquire the optical gain during EDFA amplification for lengthening the long-reach transmission distance as compared to that carried by the dual-mode optical carrier. In addition, the optical single-mode modulation is also achieved to release the RF power fading.