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Journal articles on the topic 'Oscilloscopes'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 August 2024

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1

Bai, Song, and Pengzhang Yu. "High Wideband Digital Oscilloscope Design." International Journal of Computer Science and Information Technology 3, no. 1 (June 15, 2024): 149–57. http://dx.doi.org/10.62051/ijcsit.v3n1.20.

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In most test applications, acquisition and analysis involving simultaneous processing of analog and digital signals. However, the bandwidth of most mainstream digital oscilloscopes is limited to 100 MHz, which is unable to meet the testing needs of high-frequency signals in complex electronic systems [1], and therefore, high-bandwidth digital oscilloscopes have emerged. Based on this background, this paper designs a digital oscilloscope hardware platform with high bandwidth by integrating FPGA and ARM technologies, aiming to meet the rigorous testing requirements of modern electronic systems. The FPGA module is based on the xc7s75fgga676 chip, which is mainly responsible for ADC control, data processing and frequency measurement functions. AM5708 is selected as the ARM module to realize the trigger, time base, amplitude and automatic setting functions of the oscilloscope. In order to ensure the accuracy and fidelity of waveform changes, the Sinc function interpolation method is used. This design further improves the acquisition bandwidth and processing speed on the basis of traditional MSO (Mixed Signal Oscilloscope) oscilloscopes, which is of great significance for the acquisition and processing of high-speed signals.
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2

Tankeliun, Tomaš, Oleg Zaytsev, and Vytautas Urbanavičius. "Time-base Noise Reduction Method of Sampling Osciloscope." Mokslas - Lietuvos ateitis 9, no. 3 (July 4, 2017): 277–82. http://dx.doi.org/10.3846/mla.2017.1032.

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This paper proposes a method to increase precision of sampling oscilloscopes time-base then using a new hybrid time-base architecture. The traditional time-base of sampling oscilloscope has three kinds of time base error including time base drift, time base jitter and time base distortion. New hybrid time-base architecture allows to minimize this kind of errors.
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3

Ngozi Ernest-Okoye, Kenechukwu Sylvanus Anigbogu, and Chukwudi Okwuchukwu Aniagor. "Asp. Net simulated virtual oscilloscope." International Journal of Science and Research Archive 9, no. 2 (August 30, 2023): 697–707. http://dx.doi.org/10.30574/ijsra.2023.9.2.0643.

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The Oscilloscope ranges from the CRO (Cathode Ray Oscilloscope) to DSOs (Digital Storage Oscilloscopes), which is a type of electronic test equipment that presents the dynamics of a time-varying signal as a two-dimensional pattern on a screen. Design of a virtual oscilloscope is a work that seeks to replicate the basics of power measurement of a physical oscilloscope, which is the most widely used general-purpose electronic test instrument in the laboratory but is plagued by limited supply due to high cost. As such this project bridges the gap between direct contact with the instrument and the usage of a virtual laboratory. Engineers have dealt with different spheres of this virtualization of oscilloscopes. However, this work managed to bring four different quantities; current, voltage, power, and resistance into one platform, reducing the cost and stress of having separate platforms. The work adopted Wavesurfer scope techniques and used complex AC circuits analysis to model a partial network virtualization platform, based on the ASP.NET Framework built using visual C# in Microsoft Visual Studio. The six initial inputs options: voltage and current (V-I), voltage and power (V-P), voltage and resistance (V-R), current and power (I-P), current and resistance (I-R), power and resistance (P-R) as measured on a meter of specified type (Averager or RMS), serve as physical inputs, which, combined with the operating mains frequency, is passed using dedicated algorithms to obtain the derivative Amplitudes.
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4

Yang, Chongyi, Chanpin Chen, Zhenhao Wu, Jiashun Jiang, Sicheng Su, Xue Kang, and Qingping Dou. "Multi-Channel Digital Oscilloscope Implementation over Android Device." Computer and Information Science 12, no. 2 (March 25, 2019): 58. http://dx.doi.org/10.5539/cis.v12n2p58.

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Signal monitoring and waveform analysis play a significant role in state-of-the-art signal processing and electronic measurement. Traditional oscilloscopes tend to be heavy and huge, which makes it impossible for outdoor signal measurement. In addition, most of those oscilloscopes can measure merely two signals simultaneously. This article proposes the design of multi-channel digital oscilloscope over common Android mobile device. In our system we use STM32 development board to implement up to eight input channels, data processing and wireless transmission. In addition, an Android application is designed for Wi-Fi data reception, respective waveform demonstration and derivation of each signal’s amplitude and frequency. In order to transmit up to eight digital signals simultaneously as fast as possible, we designed an algorithm where all signals’ data can be transmitted within a surprisingly small amount of wireless data. In our system test, wireless data transmission is implemented and each waveform can be recovered and demonstrated basically.
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Jiang, Jun, Huan Qu, and Shu Lin Tian. "Study on the Smart Handheld Wireless Oscilloscope." Applied Mechanics and Materials 416-417 (September 2013): 1325–30. http://dx.doi.org/10.4028/www.scientific.net/amm.416-417.1325.

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As the digital acquisition system is featured by increasingly higher technical targets and more complicated applicable conditions, the traditional digital oscilloscope has become incapable of meeting the requirements of real-time processing of sampled data and waveform display on one hand, and unqualified for field test in hard risky conditions on the other. This paper aims for comprehensively enhancing the digital oscilloscopes data processing, image display, human-machine interface and portable adaptability. To that end, it approaches the system composition of improved oscilloscope, and renders a chance to wirelessly connect the oscilloscope with any of the Smart Handheld Devices with Android operation system through the added wireless data interactive channel, which forms a smart handheld wireless oscilloscope. Such oscilloscope adopts the divisional coordination between data acquisition system and Smart Handheld Device to greatly improve data processing, waveform display and HMI, and realize wireless operation of remote test as a result.
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6

Jiang, Jun, and Shu Lin Tian. "A Method of Improving Signal Capture Ability of Digital Oscilloscope." Advanced Materials Research 721 (July 2013): 392–96. http://dx.doi.org/10.4028/www.scientific.net/amr.721.392.

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Signal capture is one of the hot spots in electronic test. As the representative of testing instrument, the signal capture ability of digital oscilloscope is normally judged by the waveform capture rate. Unilaterally improving signal acquisition ability whereas ignoring the improvement of waveform imaging mechanism and display effect can not increase the oscilloscopes waveform capture rate in real sense. Aiming at better ability of signal acquisition and waveform display effect of oscilloscope, this paper is committed to analyzing the improved structure of oscilloscope and conducting the real-time waveform imaging with hardware coprocessor array, and then studying the imaging mechanism of special 3D waveform and the impact of waveform display on waveform capture rate. In this way, the signal capture ability of oscilloscope is greatly improved and the effective waveform capture rate as high as 1,000,000 wfms/s is realized.
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7

D’Arco, Mauro, Ettore Napoli, Efstratios Zacharelos, Leopoldo Angrisani, and Antonio Giuseppe Maria Strollo. "Enabling Fine Sample Rate Settings in DSOs with Time-Interleaved ADCs." Sensors 22, no. 1 (December 29, 2021): 234. http://dx.doi.org/10.3390/s22010234.

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The time-base used by digital storage oscilloscopes allows limited selections of the sample rate, namely constrained to a few integer submultiples of the maximum sample rate. This limitation offers the advantage of simplifying the data transfer from the analog-to-digital converter to the acquisition memory, and of assuring stability performances, expressed in terms of absolute jitter, that are independent of the chosen sample rate. On the counterpart, it prevents an optimal usage of the memory resources of the oscilloscope and compels to post processing operations in several applications. A time-base that allows selecting the sample rate with very fine frequency resolution, in particular as a rational submultiple of the maximum rate, is proposed. The proposal addresses the oscilloscopes with time-interleaved converters, that require a dedicated and multifaceted approach with respect to architectures where a single monolithic converter is in charge of signal digitization. The proposed time-base allows selecting with fine frequency resolution sample rate values up to 200 GHz and beyond, still assuring jitter performances independent of the sample rate selection.
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8

Lastera, I. Wayan, and I. Putu Arsikaputra. "PEMBUATAN DAN PENGGUNAAN ALAT KONVERTER UNIVERSAL OSILOSKOP SEBAGAI PERALATAN KATAGORI 2 PADA PRAKTIKUM ELEKTRONIKA DAYA." Jurnal SPEKTRUM 7, no. 4 (December 6, 2020): 173. http://dx.doi.org/10.24843/spektrum.2020.v07.i04.p22.

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To display electric waveforms in power electronics practicum, the instrumentused is an oscilloscope. With the limited range of test voltages from oscilloscopes themeasurement results for the power electronics lab are not good enough. To improvethe results of practicum, one effort that can be done is by making an universalconverter oscilloscope tool. The potential of this universal converter tool can beidentified by using it in uncontrolled AC electricity testing, controlled AC electricitytesting, uncontrolled DC electricity testing and controlled DC electricity testing. The testdata obtained are tabulated and analyzed descriptively, in order to be able to see andbe able to infer the potential of the oscilloscope universal converter. The test resultsshow that the use of an oscilloscope universal converter able to improve themeasurement results for power electronics practicum, proven to be able to be used inAC and DC mains voltage either uncontrolled or controlled with normal waveformdisplay, so that it can be used as category 2 equipment in the power electronicspracticum, in order to add equipment to the laboratory.
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9

Gould Electronics Ltd. "High speed processing oscilloscopes." NDT & E International 24, no. 6 (December 1991): 339. http://dx.doi.org/10.1016/0963-8695(91)90137-r.

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10

Rush, K., S. Draving, and J. Kerley. "Characterizing high-speed oscilloscopes." IEEE Spectrum 27, no. 9 (September 1990): 38–39. http://dx.doi.org/10.1109/6.58452.

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11

Tyler, Neil. "Tektronix Adds New Oscilloscopes." New Electronics 52, no. 11 (June 11, 2019): 7. http://dx.doi.org/10.12968/s0047-9624(22)61299-9.

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12

Gong, Peng Wei, Zhe Ma, Hong Mei Ma, and Chun Tao Yang. "Experimental Investigation of Terahertz Temporal Response of a Photoconductive Switch." Advanced Materials Research 571 (September 2012): 491–95. http://dx.doi.org/10.4028/www.scientific.net/amr.571.491.

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Picosecond or subpicosecond electrical pulses can be generated from femtosecond laser excited photoconductive switches, and this technique is an effective method to characterize the rise time of the broadband oscilloscopes recently. In this paper, low temperature grown GaAs (LT-GaAs) is used as the substrate of the photoconductive switch which is excited by the femtosecond laser. After propagating along a coplanar waveguide, the generated terahertz pulses are transferred to a 1.85 mm coaxial cable through a microwave probe. The pulse width is measured in a 70 GHz sampling oscilloscope, the FWHM value is about 7.4 ps.
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13

Wang, Bing, Timothy R. Anderson, and Wilson Zehr. "Competitive Pricing Using Data Envelopment Analysis — Pricing for Oscilloscopes." International Journal of Innovation and Technology Management 13, no. 01 (January 28, 2016): 1650006. http://dx.doi.org/10.1142/s0219877016500061.

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The research in this paper proposes a new technique for pricing products in competitive markets taking into account the features and prices of competing product offerings. This technique is based on a methodology known as data envelopment analysis (DEA) and is referred to as competitive pricing using data envelopment analysis (CPDEA). With the development of technology accelerating and new products coming to the market at an ever faster pace, prices of current products are often adjusted based on the state-of-the-art (SOA) technology in the market in order to remain competitive. CPDEA measures the product features that are most important to customers and calculates the performance efficiency values using the DEA method. CPDEA regards price as a performance feature, using this approach the manufacturer can adjust the price in order for a product to reach the SOA frontier and maintain competitive pricing. This research demonstrates the proposed method applied to a popular product category in the test and measurement industry: oscilloscopes. The authors investigated the features of oscilloscopes that are most important to users, then a feature dataset from different oscilloscope models was collected, and the performance efficiency values of the different models were calculated. The product prices are then adjusted in order for efficiency to be as close to 1 as possible which means that the products are considered SOA in the market. In this way, we obtain a more competitive price for the older products, while also setting the prices for the advanced products in a way that captures the value of their additional features.
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14

Henderson, D., and A. G. Roddie. "Calibration of fast sampling oscilloscopes." Measurement Science and Technology 1, no. 8 (August 1, 1990): 673–79. http://dx.doi.org/10.1088/0957-0233/1/8/002.

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15

Harvey, G., M. Gilday, and T. J. Kelly. "An Inquiry Approach to Effective Use of Instrumentation: An Example from RC Circuits." Physics Teacher 60, no. 3 (March 2022): 192–94. http://dx.doi.org/10.1119/10.0009687.

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In this article, we present an intriguing experimental exercise that does not fall foul of improper use of instrumentation. The activity is designed as an electronics exercise where the role of the instruments in the measurement of the RC time constant is considered. Essentially, we study the accuracy and precision of a measurement of the RC time constant in a series circuit with an oscilloscope as a function of the value of the resistor, against the predicted linear model of τ = RC. As the value of the resistor approaches the value of the impedance of the oscilloscope, the time constant deviates from the linear model. We show how to adapt the model to account for this and create a mathematical model that agrees with the measurements. It is hoped that such an exercise will solidify a rule of effective use of oscilloscopes—that the resistance of the circuit should be much lower than the impedance of the scope—in the mind of the student.
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16

Ismail, Mahizah, Farid Minawi, Wan Zul Adli Wan Mokhtar, Noraihan L Abdul Rashid, and Ahmad K. Ariffin. "Using a web-based and stand-alone oscilloscope for physics experiment during Covid-19 pandemic." Physics Education 58, no. 1 (October 24, 2022): 015006. http://dx.doi.org/10.1088/1361-6552/ac95eb.

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Abstract Teaching alternating currents, ac or sound waves, is incomplete without an introduction to the oscilloscope. An oscilloscope is a tool that graphically displays electrical signals and shows their time dependence. However, due to the pandemic, triggered by the SARS-CoV-2 virus, many students do not have the opportunity to master the use of an oscilloscope. Face-to-face teaching activity has been interrupted in both schools and higher institutions. The sudden change to online teaching created problems among educators, especially for laboratory activities. The central issue is creating laboratory activities without going into the labs for the students to acquire the required skills, especially the basics of how to operate an oscilloscope. In order to create an opportunity and engaging environment, we suggested the use of the ‘web-based and stand-alone oscilloscope’. The software consists of a low-frequency (signal) generator (LFG), a direct current power supply, and an oscilloscope. The LFG is capable of producing several types of signal and the software is designed to aid the undergraduate engineering and physics students in learning the operation and functions of a digital storage oscilloscope. It can be used as an alternative to face-to-face laboratory activity for physics experiments. It is free and easy to use. The experiments enable students to develop the experimental and measurement skills related to signal generators and oscilloscopes. Hence it opens the opportunity of ‘doing’ virtual physics investigations individually at home.
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17

Tankeliun, Tomaš. "RESEARCH OF RELATION OF SAMPLERS FREQUENCY CHARACTERISTICS / STROBAVIMO ĮTAISO DAŽNINIŲ CHARAKTERISTIKŲ SĄRYŠIO TYRIMAS." Mokslas – Lietuvos ateitis 8, no. 3 (June 29, 2016): 282–88. http://dx.doi.org/10.3846/mla.2016.933.

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This paper proposes an algorithm to reduce limitations in band-width measurements of sampling oscilloscopes then using a swept sine-wave measurement method. The traditional swept sine-wave method allow measure only magnitude response. Phase response can be computed only if a sampler is a minimal phase circuit. In this paper alternative bandwidth measurement algorithm using the nose-to-nose method with measurements corrections for the non-idle properties of oscilloscope is de-scribed. Algorithm includes for noise, time base distortions and jitter in measurement signals corrections methods. Proposed algorithm allows to measure phase and magnitude responses when only two similar oscilloscopes and the source of sync pulse are used. Algorithm performs as well as the swept sine-wave method in case when both samplers have the same frequency characteristics. Stroboskopiniai osciloskopai skirti matuoti sparčius periodinius signalus naudojant sąlyginai nesparčius didelio skiltiškumo analoginius-skaitmeninius keitiklius. Vienas iš pagrindinių stroboskopinio osciloskopo mazgų, užtikrinančių, kad osciloskopo charakteristikos atitiktų metrologinius reikalavimus, ir kuriame vyksta matuojamo aukštadažnio signalo spektro transformacija į žemų dažnių sritį, yra strobavimo įtaisas. Šiame darbe pateikiamas strobavimo įtaiso veikimo principas, nagrinėjami įtaiso dažninių charakteristikų matavimo būdai taikant pastovios amplitudės, kintančio dažnio harmoninio virpesio ir priešpriešiais sujungtų strobavimo grandinių metodus. Gauti rezultatai rodo, kad nagrinėjamas strobavimo įtaisas nepriklauso minimalios fazės grandinių klasei ir apskaičiuoti įtaiso dažninę fazės charakteristiką (DFCh) iš dažninės amplitudės charakteristikos (DACh) neįmanoma, tačiau taikant priešpriešiais sujungtų strobavimo grandinių matavimo metodą galima gauti įtaiso DACh ir DFCh nenaudojant papildomos aukštadažnės matavimo įrangos ir mažinant matavimo proceso trukmę.
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18

Dienstfrey, A., P. D. Hale, D. A. Keenan, T. S. Clement, and D. F. Williams. "Minimum-phase calibration of sampling oscilloscopes." IEEE Transactions on Microwave Theory and Techniques 54, no. 8 (August 2006): 3197–208. http://dx.doi.org/10.1109/tmtt.2006.879167.

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19

Connolly, Walter. "A projection lens system for oscilloscopes." Physics Teacher 23, no. 8 (November 1985): 496–97. http://dx.doi.org/10.1119/1.2341895.

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20

Dias Pereira, J. Miguel. "The history and technology of oscilloscopes." IEEE Instrumentation and Measurement Magazine 9, no. 6 (December 2006): 27–35. http://dx.doi.org/10.1109/mim.2006.250640.

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21

Brown, David A., Corey Bachand, Austin Souza, Isabella Di Bona, and Jesse Kanaley. "Low cost acoustic transducer calibration system." Journal of the Acoustical Society of America 151, no. 4 (April 2022): A248. http://dx.doi.org/10.1121/10.0011217.

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An acoustic calibration system was developed primarily for underwater acoustic transducers, although applicable for a variety of acoustic applications. Historically, such systems have been large, highly customized, and very expensive. With the advent of compact cost-effective digital PC-based oscilloscopes and data acquisitions systems (e.g., devices from TiePie, Cleverscope, and Digilent), a development that began as a senior capstone-design project has recently been demonstrated. Our system is based on the TiePie Digital Oscilloscope, a PC based signal generation and acquisition systems, a power amplifier, optional preamplifier and stepper motor with controller for radiation patterns. More specifically, the receive sensor signals are acquired with a TiePie Handyscope HS6 DIFF (1000MS/s, USB 3.0 oscilloscope, with four differential analogue channels) and the transmit signal (signal generation, transmit voltage and current acquisition) utilizes a TiePie HS5-540XM 5 (500 MHz, 1-channel generator, 2-channel acquisition) measuring system. The calibration and data display is controlled with MATLAB and controlled through a graphical user interface (GUI). Examples of Transmit Pressure Response per Volt (TR/V or TVR), Free Field Voltage Sensitivity (FFVS), and Beam Pattern measurements will be provided. [Work supported by BTech Acoustics LLC.]
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22

Trung, Dinh-V., Thanh Binh Nguyen, Duy Thang Dao, Van Hai Bui, Xuan Tu Nguyen, Minh Tien Pham, Phuong Dung Truong, and T. T. Bao Nguyen. "Multichannel Photon Counting Lidar Measurements Using USB-based Digital Storage Oscilloscope." Communications in Physics 29, no. 3SI (November 4, 2019): 351. http://dx.doi.org/10.15625/0868-3166/29/3si/14332.

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We present a simple method of making multichannel photon counting measurements of weak lidar signal from large ranges, using commonly available USB-based digital storage oscilloscopes. The single photon pulses from compact photomultiplier tubes are amplified and stretched so that the pulses are large and broad enough to be sampled efficiently by the USB oscilloscopes. A software interface written in Labview is then used to count the number of photon pulses in each of the prescribed time bins to form the histogram of LIDAR signal. This method presents a flexible alternative to the modular multichannel scalers and facilitate the development of sensitive lidar systems.
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23

Kraftmakher, Yaakov. "Digital storage oscilloscopes in the undergraduate laboratory." European Journal of Physics 33, no. 6 (September 10, 2012): 1565–77. http://dx.doi.org/10.1088/0143-0807/33/6/1565.

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24

Potapov, Yu P., S. A. Zarubin, and E. B. Maramchina. "Measuring system for certification of digital oscilloscopes." Measurement Techniques 34, no. 3 (March 1991): 289–91. http://dx.doi.org/10.1007/bf00978805.

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25

Forinash, Kyle, and Raymond F. Wisman. "Smartphones as portable oscilloscopes for physics labs." Physics Teacher 50, no. 4 (April 2012): 242–43. http://dx.doi.org/10.1119/1.3694081.

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26

Naidenova, I. A., B. N. Levitas, and M. N. Dvoretskii. "Measuring the quantization instability of digital oscilloscopes." Measurement Techniques 32, no. 9 (September 1989): 907–10. http://dx.doi.org/10.1007/bf02112512.

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27

Bertocco, M., L. Garbin, and C. Narduzzi. "Correction of systematic effects in digitizing oscilloscopes." IEEE Transactions on Instrumentation and Measurement 52, no. 3 (June 2003): 871–77. http://dx.doi.org/10.1109/tim.2003.814682.

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28

Moschitta, Antonio, Fabrizio Stefani, and Dario Petri. "Measurements of Transient Phenomena With Digital Oscilloscopes." IEEE Transactions on Instrumentation and Measurement 56, no. 6 (December 2007): 2486–91. http://dx.doi.org/10.1109/tim.2007.908119.

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29

Humphreys, David A., Martin Hudlicka, and Irshaad Fatadin. "Calibration of Wideband Digital Real-Time Oscilloscopes." IEEE Transactions on Instrumentation and Measurement 64, no. 6 (June 2015): 1716–25. http://dx.doi.org/10.1109/tim.2015.2407471.

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30

Rush, K., and T. Lucero-Hall. "Two ways to catch a wave (oscilloscopes)." IEEE Spectrum 30, no. 2 (February 1993): 38–41. http://dx.doi.org/10.1109/6.208362.

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31

Manevich, V. Z., and �. F. Khamadulin. "Dynamic characteristics of cathode-ray tube oscilloscopes." Measurement Techniques 28, no. 1 (January 1985): 82–84. http://dx.doi.org/10.1007/bf00861109.

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32

D’Arco, Mauro, Ettore Napoli, and Efstratios Zacharelos. "Digital Circuit for Seamless Resampling ADC Output Streams." Sensors 20, no. 6 (March 14, 2020): 1619. http://dx.doi.org/10.3390/s20061619.

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Fine resolution selection of the sample rate is not available in digital storage oscilloscopes (DSOs), so the user has to rely on offline processing to cope with such need. The paper first discusses digital signal processing based methods that allow changing the sampling rate by means of digital resampling approaches. Then, it proposes a digital circuit that, if included in the acquisition channel of a digital storage oscilloscope, between the internal analog-to-digital converter (ADC) and the acquisition memory, allows the user to select any sampling rate lower than the maximum one with fine resolution. The circuit relies both on the use of a short digital filter with dynamically generated coefficients and on a suitable memory management strategy. The output samples produced by the digital circuit are characterized by a sampling rate that can be incoherent with the clock frequency regulating the memory access. Both a field programmable gate array (FPGA) implementation and an application specific integrated circuit (ASIC) design of the proposed circuit are evaluated.
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Perotoni, Marcelo Bender, Walter M. Silva, Danilo B. Almeida, and Kenedy M. G. Santos. "PRE-COMPLIANCE NEAR-FIELD TESTS BASED ON OSCILLOSCOPES." Progress In Electromagnetics Research M 110 (2022): 109–18. http://dx.doi.org/10.2528/pierm22032504.

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34

Clement, T. S., P. D. Hale, D. F. Williams, C. M. Wang, A. Dienstfrey, and D. A. Keenan. "Calibration of sampling oscilloscopes with high-speed photodiodes." IEEE Transactions on Microwave Theory and Techniques 54, no. 8 (August 2006): 3173–81. http://dx.doi.org/10.1109/tmtt.2006.879135.

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35

Shaw, Brian M. "Book Review: Oscilloscopes — Functional Operation and Measuring Examples." International Journal of Electrical Engineering & Education 25, no. 4 (October 1988): 349–50. http://dx.doi.org/10.1177/002072098802500412.

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36

Tougaw, D. "Agilent's mixed-signal oscilloscopes provide enhanced measurement capabilities." Computing in Science and Engineering 3, no. 3 (May 2001): 11–14. http://dx.doi.org/10.1109/mcise.2001.919260.

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37

Chou, J., J. A. Conway, G. A. Sefler, G. C. Valley, and B. Jalali. "Photonic Bandwidth Compression Front End for Digital Oscilloscopes." Journal of Lightwave Technology 27, no. 22 (November 2009): 5073–77. http://dx.doi.org/10.1109/jlt.2009.2030519.

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38

Zavyalov, N. V., V. S. Gordeev, A. V. Grishin, S. Yu Puchagin, K. V. Strabykin, D. A. Kalashnikov, D. O. Mansurov, et al. "Current and voltage monitors on a pulsed-power accelerator “Gamma-1”." International Journal of Modern Physics: Conference Series 32 (January 2014): 1460328. http://dx.doi.org/10.1142/s2010194514603287.

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There is presented a system of registering electric parameters of high-current pulsed electron accelerator “Gamma-1” its output electric power being 1.5 TW. The accelerator system of registration makes it possible to register in a single time scale the voltage pulses with the amplitude up to 3 MV, current pulses with the amplitude up to 1 MA and duration from several nanoseconds to a microsecond. Into the system of registration there are included two-step resistive voltage dividers, capacitive voltage divider, Rogowski coils, sectionalized Rogowski coils, B-dots, shunts, transmission line, attenuators, oscilloscopes, program system. The program system is aimed at reading, transmitting and processing information from oscilloscopes on the archival computer and provides interaction with database of current and voltage sensors, cables and filters. For each registration session the system also forms a map of experiment where system configuration and experiment parameters are presented.
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39

Greitans, M., V. Aristov, and E. Hermanis. "Amplitude-frequency band control for oscilloscopes and signal converters." Automatic Control and Computer Sciences 45, no. 4 (August 2011): 218–22. http://dx.doi.org/10.3103/s0146411611040043.

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40

Henderson, D., A. G. Roddie, and A. J. A. Smith. "Recent developments in the calibration of fast sampling oscilloscopes." IEE Proceedings A Science, Measurement and Technology 139, no. 5 (1992): 254. http://dx.doi.org/10.1049/ip-a-3.1992.0044.

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41

Levitas, B. N., V. S. Roizentok, Ya M. Rossoskii, and �. I. Shapiro. "Improving the accuracy of amplitude measurements by sampling oscilloscopes." Measurement Techniques 29, no. 2 (February 1986): 127–31. http://dx.doi.org/10.1007/bf00868836.

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42

Pan, Zhixiang, Peng Ye, Kuojun Yang, Jian Gao, Wuhuang Huang, and Yu Zhao. "Frequency response mismatch calibration in 2-channel time-interleaved oscilloscopes." Review of Scientific Instruments 92, no. 6 (June 1, 2021): 064711. http://dx.doi.org/10.1063/5.0045533.

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43

Gans, W. L. "Dynamic calibration of waveform recorders and oscilloscopes using pulse standards." IEEE Transactions on Instrumentation and Measurement 39, no. 6 (1990): 952–57. http://dx.doi.org/10.1109/19.65804.

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44

HANAJIMA, Naohiko, Mitsuhisa YAMASHITA, Toshiharu KAZAMA, Tomonori YUASA, and Hiromitsu HIKITA. "3615 Introduction of USB oscilloscopes to a robot programming exercise." Proceedings of the JSME annual meeting 2008.5 (2008): 187–88. http://dx.doi.org/10.1299/jsmemecjo.2008.5.0_187.

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45

Cho, Chihyun, Joo Gwang Lee, Paul D. Hale, Jeffrey A. Jargon, Peter Jeavons, John B. Schlager, and Andrew Dienstfrey. "Calibration of Time-Interleaved Errors in Digital Real-Time Oscilloscopes." IEEE Transactions on Microwave Theory and Techniques 64, no. 11 (November 2016): 4071–79. http://dx.doi.org/10.1109/tmtt.2016.2614928.

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46

Hale, Paul D., C. M. Wang, Dylan F. Williams, Kate A. Remley, and Joshua D. Wepman. "Compensation of Random and Systematic Timing Errors in Sampling Oscilloscopes." IEEE Transactions on Instrumentation and Measurement 55, no. 6 (December 2006): 2146–54. http://dx.doi.org/10.1109/tim.2006.880270.

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47

Wang, C. M., P. D. Hale, and K. J. Coakley. "Least-squares estimation of time-base distortion of sampling oscilloscopes." IEEE Transactions on Instrumentation and Measurement 48, no. 6 (1999): 1324–32. http://dx.doi.org/10.1109/19.816156.

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48

Cervi, A., A. Roncarati, and M. Melloni. "The use of PicoScope usb oscilloscopes in electric grid monitoring system." ELECTRONICS: Science, Technology, Business, no. 8 (2017): 110–14. http://dx.doi.org/10.22184/1992-4178.2017.169.8.110.114.

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49

Panikumar, K. G., and T. N. Ruckmongathan. "A Controller for Liquid Crystal Displays in Logic Analyzers and Oscilloscopes." Journal of Display Technology 1, no. 1 (September 2005): 82–89. http://dx.doi.org/10.1109/jdt.2005.853353.

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50

Berg, Klaus-Peter. "Messunsicherheitsbetrachtung bei der Oszilloskopkalibrierung (Evaluation of Measurement Uncertainty in Calibrating Oscilloscopes)." tm - Technisches Messen 71, no. 2-2004 (February 2004): 122–25. http://dx.doi.org/10.1524/teme.71.2.122.27063.

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