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PicoScope 9300 Series  

PicoScope 9300 Series

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PicoScope® 9300 시리즈 


USB 샘플링 오실로스코프

Sampling Oscilloscopes to 25 GHz with TDR/TDT and Optical models

25GHz와 TDR/TDT 그리고 광학 모델의 샘플링 오실로스코프

15 to 25 GHz electrical, 9.5 GHz optical, TDR/TDT, 2-channel and 4-channel, compact, portable, USB instruments.

15 ~ 25GHz 전기, 9.5GHz 과학, TDF-TDT 2채널과 4채널, 소형, 휴대용, USB형 장비

These units occupy very little space on your workbench and are small enough to carry with your laptop for on-site testing, but that’s not all. 

이 장비는 작은 사이즈로 많은 공간을 필요로 하지않으며 휴대하기 편해 노트북과 편하게 테스트할 수 있습니다. 그 뿐만 아닙니다.

Instead of using remote probe heads attached to a large bench-top unit, you can position the scope right next to the device under test. Now all that lies between your scope and the DUT is a short, low-loss coaxial cable. 

벤치 탑 장치에 연결된 원격 프로브 헤드를 사용하는 대신 테스트 장비 바로 옆에 스코프를 위치하실 수 있습니다. 

스코프와 DUT 사이에 있는 모든것은 짧은 저손실 동축 케이블 입니다.

Everything you need is built into the oscilloscope, with no expensive hardware or software add-ons to worry about.

필요한건 모두 오실로스코프 안에 내장되어있으며 비산 하드웨어나 소프트웨어가 합쳐져 걱정하실 필요가 없습니다.

Key features

▶ 15 TS/s (64 fs) sequential sampling 15TS/s[64fs] 시퀀셜 샘플링

▶ Up to 15 GHz prescaled, 2.5 GHz direct trigger and 11.3 Gb/s clock recovery 최대 15GHz 프레스케일, 2.5GHz 트리거와 11.3Gb/s의 클록 리커버리

▶ Industry-leading 16-bit 1 MS/s ADC and 60 dB dynamic range 16비트

▶ Eye and mask testing to 16 Gb/s with up to 223–1 pattern lock   Eye, 마스크 테스트 16Gb/s와 최대 패턴락 223-1

▶ Intuitive, touch-compatible Windows user interface 직관적인 터치 호환 윈도우 유저 인터페이스

▶ Comprehensive built-in measurements, histogramming and editable data mask library 포괄적인 내장 측정, 히스토그램, 편집 가능한 데이터 마스크 라이브러리

▶ Integrated, differential, deskewable TDR/TDT step generator 

Applications include

▶ Telecom and radar test, service and manufacturing

▶ Optical fiber, transceiver and laser testing

▶ RF, microwave and gigabit digital system measurements

▶ Ethernet, HDMI 1 and 2, USB 2 and 3, PCI, SATA

▶ Semiconductor characterization

▶ TDR/TDT analysis of cables, connectors, backplanes, PCBs and networks




25 GHz bandwidth in a compact USB instrument

소형 USB 기기 안의 25GHz 대역폭

PicoScope 9300 Series sampling oscilloscopes use triggered sequential sampling to capture high-bandwidth repetitive or clock-derived signals without the expense or jitter of a very high-speed clocked sampling system such as a real-time oscilloscope.

PicoScope 9300시리즈 샘플링의 오실로스코프 

 25 GHz bandwidth allows measurement of 14 ps transitions, and low sampling jitter enables timing resolution down to 0.064 ps. Sequential sampling rate of 1 MS/s, unsurpassed by other sampling oscilloscopes, enables rapid building of waveforms, eye diagrams and histograms.

These two and four channel units occupy very little space on a workbench and are small enough to carry with a laptop for on-site testing. Furthermore, instead of using remote probe heads attached to a large bench-top unit, you can position the PicoScope 9300 right next to the device under test and connect to it with short, low-loss coaxial cables.

Everything you need is built into the oscilloscope, with no expensive hardware or software add-ons to worry about. Alternatively, you can use your PicoScope 9300 with a stand-alone PG900 TDR/TDT differential fast pulse generator to gain the extra versatility and configurability of independent high-performance source and measurement instruments.

Trigger modes

2.5 GHz direct and up to 15 GHz prescaled trigger

Sampling oscilloscopes accept their trigger from a separate input, either directly for repetition rates up to 2.5 GHz or via a prescaling divider input, for repetition rates up to 15 GHz (14 GHz on 15 and 20 GHz models).

Built-in 11.3 Gb/s clock data recovery trigger

To support serial data applications in which the data clock is not available as a trigger, or for which trigger jitter needs to be reduced, the PicoScope 9302 and 9321 include a clock recovery module. This continuously regenerates the data clock from the incoming serial data or trigger signal and can do so with reduced jitter even over very long trigger delays or for pattern lock applications. A divider accessory kit is included to route the signal to both the clock recovery and oscilloscope inputs.


9.5 GHz optical model


The PicoScope 9321-20 includes a built-in precision optical-to-electrical

converter. With the converter output routed to one of the scope inputs

(optionally through an SMA pulse shaping filter), the PicoScope 9321-20 can analyze standard optical communications signals such as OC48/STM16, 4.250 Gb/s Fibre Channel and 2xGB Ethernet. The scope can perform eyediagram measurements with automatic measurement of optical parameters including extinction ratio, S/N ratio, eye height and eye width. With its integrated clock recovery module, the scope is usable to 11.3 Gb/s.

The converter input accepts both single-mode (SM) and multi-mode (MM)

fibers and has a wavelength range of 750 to 1650 nm.

TDR/TDT analysis


The PicoScope 9311 oscilloscopes feature built-in step generators for time-domain reflectometry and transmission measurements. The 9311-15 integrates a single rising step generator suited to single-ended TDR/TDT applications, while the 9311‑20 features deskewable rising and falling step generators suited to single-ended and differential measurements. These features can be used to characterize transmission lines, printed circuit traces, connectors and cables with 16 mm resolution for impedance measurements and 4 mm resolution for fault detection.


The PicoScope 9311-15 and 9311-20 generate 2.5 to 7 V steps with 60 ps rise time from built-in step recovery diodes. They are supplied with a comprehensive set of calibrated accessories to support your TDR/TDT measurements, including cables, signal dividers, adaptors, attenuator and reference load and short.

The PicoScope 9311-20 TDR/TDT model includes source deskew with 1 ps resolution and comprehensive calibration, reference plane and measurement functions. Voltage, impedance or reflection coefficient (ρ) can be plotted against time or distance.

An alternative approach to TDR/TDT capability is to pair any 9300 Series scope with a standalone PG900 pulse generator. These instruments include similar differential step recovery diode step generators and also offer an option of 40 ps tunnel diode step generation. This brings extra flexibility and the ability to remotely position the pulse source. The generators also enable TDT and TDR with the PicoScope 9301, 9302 clock recovery, 9321 optical and 9341 4-channel sampling oscilloscopes.


Built-in signal generator


All the PicoScope 9300 Series scopes can generate industry-standard and custom signals including clock, pulse and pseudo-random binary sequence. You can use these to test the instrument’s inputs, experiment with its features and verify complex setups such as mask tests. AUX OUTPUT can also be configured as a trigger output.

PicoConnect® 900 Series: the shape of probes to come


 The PicoConnect 900 Series is a range of low-invasive, high-frequency passive probes, designed for microwave and gigabit applications up to 9 GHz and 18 Gb/s. They deliver unprecedented performance and flexibility at a low price and are an obvious choice to use alongside the PicoScope 9300 Series scopes.

Features of the PicoConnect 900 Series probes

Extremely low loading capacitance of < 0.3 pF typical, 0.4 pF upper test limit for all models

Slim, fingertip design for accurate and steady probing or solder-in at fine scale

Interchangeable SMA probe heads at division ratios of 5:1, 10:1 and 20:1, AC or DC coupled

Accurate probing of high speed transmission lines for Z0 = 0 Ω to 100 Ω

Class-leading uncorrected pulse/eye response and pulse/eye disturbance

PicoSource® PG900 Series differential pulse generators


For greater versatility than a built-in signal generator can offer, you may want to separate your high-performance fast-step TDR/TDT pulse source from the sampling oscilloscope and have two instruments to use either stand-alone or together as required.

The PicoSource PG900 Series generators contain the same step recovery diode pulse source as the PicoScope 9311, or slightly faster but reduced amplitude tunnel diode pulse heads, rehoused in a separate USB-controlled instrument. All are supplied with PicoSource PG900 control software.

SMA Bessel-Thomson pulse-shaping filters



For use with the 9321-20 optical to electrical converter, a range of Bessel–Thomson filters is available for standard bit rates. These filters are essential for accurate characterization of signals emerging from an optical transmission system.

 The first eye diagram, above left, shows the ringing typical of an unequalized O/E converter output at 622 Mb/s. The second eye diagram, above right, shows the result of connecting the 622 Mb/s B-T filter. This is an accurate representation of the signal that an equalized optical receiver would see, enabling the PicoScope 9321 to display correct measurements.

Application-configurable PicoSample 3 oscilloscope software


Designed for ease of use

The PicoSample 3 workspace takes full advantage of your available display size and resolution. You decide how much space to give to the trace display and the measurements display, and whether to open or hide the control menus. The user interface is fully touch- or mouse-operable, with grabbing and dragging of traces, cursors, regions and parameters. There are enlarged parameter controls for use on smaller touch displays. To zoom, either draw a zoom window or use the more traditional dual timebase, delay and scaling controls.

A choice of screen formats

When working with multiple traces, you can display them all on one grid or separate them into two or four grids. You can also plot signals in XY mode with or without additional voltage-time grids. The persistence display modes use color-coding or shading to show statistical variations in the signal. Trace display can be in either dots-only or vector format.

Eye-diagram analysis



The PicoScope 9300 Series scopes quickly measure more than 30 fundamental parameters used to characterize non‑return‑to‑zero (NRZ) signals and return-to-zero (RZ) signals. Up to ten parameters can be measured simultaneously, with comprehensive statistics also shown.

The measurement points and levels used to generate each parameter can optionally be drawn on the trace.

Eye-diagram analysis can be made even more powerful with the addition of mask testing, as described below.

Pattern sync trigger and eye line mode


When a repeating data pattern such as a pseudorandom bit sequence is present, an internal trigger divider can lock to it. You can then use eye-line mode to move the trigger point, and view point, along the whole pattern, bit by bit. Eye-line scan mode is also available to build an eye diagram from a user-selected range of bit intervals through to the whole pattern. These features are useful for analyzing data-dependent waveshapes.

Mask testing

PicoSample 3 has a built-in library of over 160 masks for testing data eyes. It can count or capture mask hits or route them to an alarm or acquisition control. You can stress-test against a mask using a specified margin, and locally compile or edit masks.

There’s a choice of gray-scale and color-graded display modes to aid in analyzing noise and jitter in eye diagrams. There is also a statistical display showing a failure count for both the original mask and the margin.

The extensive menu of built-in test waveforms is invaluable for checking your mask test setup before using it on live signals.

Measurement of over 100 waveform parameters with statistics


The PicoScope 9300 Series scopes quickly measure well over 100 standard waveform and eye parameters, either for the whole waveform or constrained between markers. The markers can also make on-screen ruler measurements, so you don’t need to count graticules or estimate the waveform’s position. Up to ten simultaneous measurements are possible. The measurements conform to IEEE standard definitions, but you can edit them for non-standard thresholds and reference levels using the advanced menu or by dragging the on-screen thresholds and levels. You can apply limit tests to up to four measured parameters.

A dedicated frequency counter shows signal frequency at all times, regardless of measurement and timebase settings.

Powerful mathematical analysis


The PicoScope 9300 Series scopes support up to four simultaneous mathematical combinations or functional transformations of acquired waveforms.

You can select any of the mathematical functions to operate on either one or two sources. All functions can operate on live waveforms, waveform memories or even other functions. There is also a comprehensive equation editor for creating custom functions of any combination of source waveforms.

  • Choose from 61 math functions, or create your own
  • Add, Subtract, Multiply, Divide, Invert, Absolute, Exponent, Logarithm, Differentiate, Integrate, Inverse, FFT, Interpolation, Smoothing

FFT analysis


All PicoScope 9300 Series oscilloscopes can calculate real, imaginary and complex Fast Fourier Transforms of input signals using a range of windowing functions. The results can be further processed using the math functions. FFTs are useful for finding crosstalk and distortion problems, adjusting filter circuits designed to filter out certain harmonics in a waveform, testing impulse responses of systems, and identifying and locating noise and interference sources.

강력한 수학적 분석


Behind the powerful measurement and display capabilities of the 9300 Series lies a fast, efficient data histogramming capability. A powerful visualization and analysis tool in its own right, the histogram is a probability graph that shows the distribution of acquired data from a source within a user-definable window.

Histograms can be constructed on waveforms on either the vertical or horizontal axes. The most common use for a vertical histogram is measuring and characterizing noise and pulse parameters. A horizontal histogram is typically used to measure and characterize jitter.


Software Development Kit


The PicoSample 3 software can operate as a stand-alone oscilloscope program or under ActiveX remote control. The ActiveX control conforms to the Windows COM interface standard so that you can embed it in your own software. Unlike more complex driver-based programming methods, ActiveX commands are text strings that are easy to create in any programming environment. Programming examples are provided in Visual Basic (VB.NET), MATLAB, LabVIEW and Delphi, but you can use any programming language or standard that supports the COM interface, including JavaScript and C. National Instruments LabVIEW drivers are also available. All the functions of the PicoScope 9300 and the PicoSample software are accessible remotely.

The SDK consists of the PicoSample 3 software download and a comprehensive programmer's guide, both available from picotech.com, and example code freely available from our GitHub organization page, github.com/picotech. The SDK can control the oscilloscope over the USB or the LAN port.

히스토그램 분석

9400 시리즈의 강력한 측정 및 디스플레이 기능 뒤에는 빠르고 효율적인 데이터 히스토그램

기능이 숨어 있습니다. 9400 시리즈에 탑재된 강력한 시각화 및 분석 도구인 히스토그램은

소스로부터 획득한 데이터의 분포를 사용자 정의 가능한 창에 표시한 확률 그래프입니다.

히스토그램은 세로축 또는 가로축상에 파형이 놓이도록 구성할 수 있습니다. 세로 히스토그램은

주로 노이즈 및 펄스 파라미터의 측정과 특성 분석에 사용됩니다. 가로 히스토그램은 일반적으로

지터 측정과 특성 분석에 사용됩니다.

소프트웨어 개발 키트


PicoSample 4 소프트웨어는 자립형 오실로스코프 프로그램 형태나 ActiveX 원격 제어 모드로

작동할 수 있습니다. ActiveX 제어는 Windows COM 인터페이스 표준을 준수하므로, 사용자의

소프트웨어에 임베딩할 수 있습니다. 복잡한 드라이버 기반 프로그래밍 방법과 달리, ActiveX

명령은 어느 프로그래밍 환경에서도 쉽게 생성할 수 있는 문자열입니다. 프로그래밍 예시는

Visual Basic(VB.NET), MATLAB, LabVIEW, Delphi로 제공되지만, JavaScript나 C와 같이

COM 인터페이스를 지원하는 모든 프로그래밍 언어 또는 표준을 사용할 수 있습니다. National

Instruments의 LabVIEW 드라이버도 사용할 수 있습니다. PicoScope 9400 및 PicoSample

소프트웨어의 모든 기능은 원격으로 액세스할 수 있습니다.

Pico는 ActiveX 제어 기능이 자세히 설명된 종합 프로그래머 가이드를 제공합니다. SDK는 USB

또는 LAN 포트를 통해 오실로스코프를 제어할 수 있습니다.


PicoScope 9400 시리즈 입력, 출력 및 표시기


전원 LED: 정상 작동 시 녹색

상태/트리거 LED: 연결 진행 및 트리거 표시

채널 입력: PicoScope 9404 입력 채널 4개: 채널 1~4 샘플링 속도에 영향을 미치지 않고 채널을

몇 개든 활성화할 수 있습니다. 활성화된 채널 간에는 캡처 메모리(250 kS)만 공유됩니다.

내장형 CAL 테스트 신호: 보정기 출력(CAL OUT)은 DC, 1 kHz 또는 가변 주파수 구형파 출력을

제공합니다. 스코프 입력을 확인하는 데 사용됩니다.

트리거 출력: 외부 장치를 PicoScope 9404의 상승 에지, 하강 에지 및 홀드오프 트리거 끝에

동기화하는 데 사용됩니다.



RST(초기화 버튼) USB: USB 2.0 포트는 오실로스코프를 PC에 연결하는 데 사용됩니다.
USB 호스트가 감지되지 않을 경우 오실로스코프는 LAN 포트를 통해 연결을 시도합니다.
LAN: 처음에는 USB 포트 연결로 LAN 설정을 공급해야 합니다. 구성이 완료된 다음 부터는 USB 호스트가 감지되지 않을 경우 오실로스코프는 LAN 포트를 사용합니다.
PicoSample 4 소프트웨어에서 8개의 PicoScope 9400 장치 중 1개의 주소를 지정할 수 있습니다.
12 V DC 입력: 오실로스코프와 함께 공급된 접지된 상용 전원 어댑터만 사용할 것











PicoScope 9300 specifications

Oscilloscope – vertical (analog)9300-15 models9300-20 models9300-25 models
Number of channelsPicoScope 9341: 4
All other models: 2
Acquisition timingSelectable simultaneous or alternate acquisition
Bandwidth, Full15 GHz20 GHz25 GHz
Bandwidth, Narrow8 GHz10 GHz12 GHz
Pulse response rise time, full bandwidth23.4 ps (10% to 90%, calculated)17.5 ps (10% to 90%, calculated)14.0 ps (10% to 90%, calculated)
Pulse response rise time, narrow bandwidth43.8 ps (10% to 90%, calculated)35.0 ps (10% to 90%, calculated)29.2 ps (10% to 90%, calculated)
Noise, full bandwidth< 1.2 mV RMS typical, < 1.6 mV RMS maximum< 1.5 mV RMS typical, < 2.0 mV RMS maximum< 1.9 mV RMS typical, < 2.5 mV RMS maximum
Noise, narrow bandwidth< 0.7 mV RMS typical, < 0.9 mV RMS maximum< 0.8 mV RMS typical, < 1.1 mV RMS maximum< 1.0 mV RMS typical, < 1.3 mV RMS maximum
Noise with averaging100 μV RMS system limit, typical
Operating input voltage with digital feedback1 V p-p with ±1 V range (single-valued)
Operating input voltage without digital feedback±400 mV relative to channel offset (multi-valued)
Sensitivity1 mV/div to 500 mV/div in 1-2-5 sequence with 0.5% fine increments
Resolution16 bits, 40 μV/LSB
Accuracy±2% of full scale ±2 mV over nominal temperature range (assuming temperature-related calibrations are performed)
Nominal input impedance(50 ±1) Ω
Input connectors2.92 mm (K) female, compatible with SMA and PC3.5
Timebase (Sequential time sampling mode)
Ranges5 ps/div to 3.2 ms/div (main, intensified, delayed, or dual delayed)
Delta time interval accuracyFor > 200 ps/div: ±0.2% of delta time interval ± 12 ps
For < 200 ps/div: ±5% of delta time interval ± 5 ps
Time interval resolution64 fs
Channel deskew1 ps resolution, 100 ns max.
Trigger sourcesAll models: external direct, external prescaled, internal direct and internal clock triggers.
PicoScope 9302 and 9321 only: external clock recovery trigger
External direct trigger bandwidth and sensitivityDC to 100 MHz : 100 mV p-p; to 2.5 GHz: 200 mV p-p
External direct trigger jitter1.8 ps RMS (typ.) or 2.0 ps RMS (max.) + 20 ppm of delay setting
Internal direct trigger bandwidth and sensitivityDC to 10 MHz: 100 mV p-p; to 100 MHz: 400 mV p-p (channels 1 and 2 only)
Internal direct trigger jitter25 ps RMS (typ.) or 30 ps RMS (max.) + 20 ppm of delay setting (channels 1 and 2 only)
External prescaled trigger bandwidth and sensitivity1 to 14 GHz, 200 mV p-p to 2 V p-p1 to 14 GHz, 200 mV p-p to 2 V p-p
14 to 15 GHz, 500 mV p-p to 2 V p-p
External prescaled trigger jitter1.8 ps RMS (typ.) or 2.0 ps RMS (max.) + 20 ppm of delay setting
Pattern sync trigger clock frequency10 MHz to 14 GHz10 MHz to 14 GHz10 MHz to 15 GHz
Pattern sync trigger pattern length7 to 8 388 607 (223− 1)
Clock recovery (PicoScope 9302 and 9321)
Clock recovery trigger data rate and sensitivity6.5 Mb/s to 100 Mb/s: 100 mV p-p
>100 Mb/s to 11.3 Gb/s: 20 mV p-p
Recovered clock trigger jitter1 ps (typ.) or 1.5 ps (max.) + 1.0% of unit interval
Maximum safe trigger input voltage±2 V (DC + peak AC)
Input characteristics50 Ω, AC coupled
Input connectorSMA (F)
ADC resolution16 bits
Digitizing rate with digital feedback (single-valued)DC to 1 MHz
Digitizing rate without digital feedback (multi-valued)DC to 40 kHz
Acquisition modesSample (normal), average, envelope
Data record length32 to 32 768 points (single channel) in x2 sequence
StylesDots, vectors, persistence, gray-scaling, color-grading
Persistence timeVariable or infinite
Screen formatsAuto, single YT, dual YT, quad YT, XY, XY + YT, XY + 2 YT
Measurement and analysis
MarkersVertical bars, horizontal bars (measure volts) or waveform markers
Automatic measurementsUp to 10 at once
Measurements, X parametersPeriod, frequency, pos/neg width, rise/fall time, pos/neg duty cycle, pos/neg crossing, burst width, cycles, time at max/min, pos/neg jitter ppm/RMS
Measurements, Y parametersMax, min, top, base, peak-peak, amplitude, middle, mean, cycle mean, AC/DC RMS, cycle AC/DC RMS, pos/neg overshoot, area, cycle area
Measurements, trace-to-traceDelay 1R-1R, delay 1F-1R, delay 1R-nR, delay 1F-nR, delay 1R-1F, delay 1F-1F, delay 1R-nF, delay 1F-nF, phase deg/rad/%, gain, gain dB
Eye measurements, X NRZArea, bit rate, bit time, crossing time, cycle area, duty cycle distortion abs/%, eye width abs/%, rise/fall time, frequency, period, jitter p-p/RMS
Eye measurements, Y NRZAC RMS, average power lin/dB, crossing %/level, extinction ratio dB/%/lin, eye amplitude, eye height lin/dB, max/min, mean, middle, pos/neg overshoot, noise p-p/RMS one/zero level, p-p, RMS, S/N ratio lin/dB
Eye measurements, X RZArea, bit rate/time, cycle area, eye width abs/%, rise/fall time, jitter p-p/RMS fall/rise, neg/pos crossing, pos duty cycle, pulse symmetry, pulse width
Eye measurements, Y RZAC RMS, average power lin/dB, contrast ratio lin/dB/%, extinction ratio lin/dB/%, eye amplitude, eye high lin/dB, eye opening, max, min, mean, middle, noise p-p/RMS one/zero, one/zero level, peak-peak, RMS, S/N
HistogramVertical or horizontal
Math functions
MathematicsUp to four math waveforms can be defined and displayed
Math functions, arithmetic+, −, ×, ÷, ceiling, floor, fix, round, absolute, invert, (x+y)/2, ax+b
Math functions, algebraicex, ln, 10x, log10, ax, loga, d/dx, integrate, x2, sqrt, x3, xa, x−1, sqrt(x2 +y2)
Math functions, trigonometricsin, sin−1, cos, cos−1, tan, tan−1, cot, cot−1, sinh, cosh, tanh, coth
Math functions, FFTComplex FFT, complex inverse FFT, magnitude, phase, real, imaginary
Math functions, combinatorial logicAND, NAND, OR, NOR, XOR, XNOR, NOT
Math functions, interpolationLinear, sin(x)/x, trend, smoothing
Math functions, otherCustom formula
FFTUp to two FFTs simultaneously
FFT window functionsRectangular, Hamming, Hann, flat-top, Blackman–Harris, Kaiser–Bessel
Eye diagramAutomatically characterizes NRZ and RZ eye patterns based on statistical analysis of waveform
Mask tests
Mask geometryAcquired signals are tested for fit outside areas defined by up to eight polygons. Standard or user-defined masks can be selected.
Built-in masks, SONET/SDHOC1/STMO (51.84 Mb/s) to FEC 1071 (10.709 Gb/s)
Built-in masks, Ethernet1.25 Gb/s 1000Base-CX Absolute TP2 to 10xGB Ethernet (12.5 Gb/s)
Built-in masks, Fibre ChannelFC133 (132.8 Mb/s) to 10x Fibre Channel (10.5188 Gb/s)
Built-in masks, PCI ExpressR1.0a 2.5G (2.5 Gb/s) to R2.1 5.0G (5 Gb/s)
Built-in masks, InfiniBand2.5G (2.5 Gb/s) to 5.0G (5 Gb/s)
Built-in masks, XAUI3.125 Gb/s
Built-in masks, RapidIOLevel 1, 1.25 Gb/s to 3.125 Gb/s
Built-in masks, SATA1.5G (1.5 Gb/s) to 3.0G (3 Gb/s)
Built-in masks, ITU G.703DS1 (1.544 Mb/s) to 155 Mb (155.520 Mb/s)
Built-in masks, ANSI T1.102DS1 (1.544 Mb/s) to STS3 (155.520 Mb/s)
Built-in masks, G.984.2XAUI-E Far (3.125 Gb/s)
Built-in masks, USBUSB 3.0 (5 Gb/s), USB 3.1 (10 Gb/s)
Signal generator output
ModesPulse, PRBS NRZ/RZ, 500 MHz clock, trigger out
Period range, pulse mode8 ns to 524 μs
Bit time range, NRZ/RZ mode4 ns to 260 μs
NRZ/RZ pattern length27−1 to 215−1
TDR pulse outputsPicoScope 9311-15PicoScope 9311-20
Number of output channels12 (1 differential pair)
Output enableYesIndependent or locked control for each source
Pulse polarityPositive-going from zero voltsChannel 1: positive-going from zero volts
Channel 2: negative-going from zero volts
Rise time (20% to 80%)60 ps guaranteed
Amplitude2.5 V to 7 V into 50 Ω
Amplitude adjustment5 mV increments
Amplitude accuracy±10%
Output amplitude safety limitAdjustable from 2.5 V to 8 V
Output pairingN/AAmplitudes and limit paired or independent
Period range1 μs to 60 ms
Period accuracy±100 ppm
Width range200 ns to 4 μs, 0% to 50% duty cycle
Width accuracy±10% of width ±100 ns
Deskew between outputsN/A−1 ns to +1 ns typical, in 1 ps increments
Timing modesStep, coarse timebase, pulse
Impedance50 Ω
Connectors on scopeSMA(f)SMA(f) x 2
TDR pre-trigger output 
PolarityPositive-going from zero volts
Amplitude700 mV typical into 50 Ω
Pre-trigger25 ns to 35 ns typical, adjustable in 5 ps increments
Pre-trigger to output jitter2 ps max. 
TDT systemPicoScope 9311-15PicoScope 9311-20
Number of TDT channels12
Incident rise time (combined oscilloscope and pulse generator, 10% to 90%)65 ps or less60 ps or less, each polarity
Jitter3 ps + 20 ppm of delay setting, RMS, max.
Corrected rise timeMin. 50 ps or 0.1 x time/div, whichever is greater, typical
Max. 3 x time/div, typical
Corrected aberrations= 0.5% typical
TDR systemPicoScope 9311-15PicoScope 9311-20
Number of channels12
Incident rise time (combined oscilloscope, step generator and TDR kit, 10% to 90%)65 ps or less60 ps or less, each polarity
Reflected step amplitude, from short or open25% of input pulse amplitude, typical
Reflected rise time (combined oscilloscope, step generator and TDR kit, 10% to 90%)65 ps or less @ 50 Ω termination60 ps or less @ 50 Ω termination, each polarity
Corrected rise timeMinimum: 50 ps or 0.1 x time/div, whichever is greater, typical.
Maximum: 3 x time/div, typical.
Corrected aberration≤ 1% typical
Measured parametersPropagation delay, gain, gain dB
TDR/TDT scaling 
TDT vertical scalevolts, gain (10 m/div to 100 /div)
TDR vertical scaleVolts, rho (10 mrho/div to 2 rho/div), ohm (1 ohm/div to 100 ohm/div)
Horizontal scaleTime (800 ns/div max.) or distance (meter, foot, inch)
Distance preset unitsPropagation velocity (0.1 to 1.0) or dielectric constant (1 to 100)
Optical/electrical converter (PicoScope 9321-20)
Bandwidth (−3 dB)9.5 GHz typical
Effective wavelength range750 nm to 1650 nm
Calibrated wavelengths850 nm (MM), 1310 nm (MM/SM), 1550 nm (SM)
Transition time51 ps typical (10% to 90% calculated from tR = 0.48/optical BW)
Noise4 μW (1310 & 1550 nm), 6 μW (850 nm) maximum @ full electrical bandwidth
DC accuracy±25 μW ±10% of full scale
Maximum input peak power+7 dBm (1310 nm)
Fiber inputSingle-mode (SM) or multi-mode (MM)
Fiber input connectorFC/PC
Input return lossSM: −24 dB typical
MM: −16 dB typical, −14 dB maximum
Temperature range, operating+5 °C to +35 °C
Temperature range for stated accuracyWithin 2 °C of last autocalibration
Temperature range, storage−20 °C to +50 °C
Calibration validity period1 year
Power supply voltage+12 V DC ± 5%
Power supply current1.7 A max.
Mains adaptorUniversal adaptor supplied
PC connectionUSB 2.0 (compatible with USB 3.0)
LAN connection10/100 Mbit/s
PC requirementsMicrosoft Windows XP (SP2 or SP3), Vista, 7, 8 or 10.
32‑bit or 64‑bit versions.
Dimensions170 mm x 285 mm x 40 mm (W x D x H)
Weight1.3 kg max.
ComplianceFCC (EMC), CE (EMC and LVD)
Warranty5 years
15 GHz sampling oscilloscopetick tick tick    
20 GHz sampling oscilloscope     tickticktick 
25 GHz sampling oscilloscope tick tick    tick
2 channelstickticktickticktickticktick  
4 channels       ticktick
Clock recovery (11.3 Gb/s)  ticktick  tick  
Optical input (9.5 GHz)      tick  
Integrated TDR/TDT (60 ps / 2.5 to 7 V)    ticktick   
Buy now
Add External PG900 TDR/TDT Sourcetickticktickticktickticktickticktick

*PG900 pulse generator can be used in addition to the built in TDR/TDT source.

Typical applications

Telecom and radar test, service and manufacturing
Optical fiber, transceiver and laser testing
RF, microwave and gigabit digital system measurements
Radar bands I, G, P, L, S, C, X, Ku
Precision timing and phase analysis
Digital system design and characterization
Eye diagram, mask and limits test to 10 Gb/s
Ethernet, HDMI 1, HDMI 2, PCI, SATA, USB 2.0, USB 3.0
TDR/TDT analysis of cables, connectors, backplanes, PCBs and networks
Optical fiber, transceiver and laser test
Semiconductor characterization
Remember: the price you pay for your PicoScope Sampling Oscilloscope is the price you pay for everything – we don’t charge you for software features or updates.
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상품명 PicoScope 9300 Series
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