PicoScope 2207B 70MHz 2-channel oscilloscope

Pico Technology
PicoScope 2207B 70 MHz 2-channel oscilloscope
  • Beskrivelse
  • Mere information
  • Specifikationer
  • 2 analogue channels
  • 70 MHz analog bandwidth
  • 1 GS/s real-time sampling
  • 64 MS buffer memory
  • 80,000 waveforms per second
  • Arbitrary Waveform Generator
  • USB 2.0 (USB 3.0 compatible) connected and powered
  • Serial decoding, FFT and mask testing as standard
  • Windows, Linux and Mac software
  • 70 MHz 2-channel oscilloscope with Arbitrary Waveform Generator and function generator.
    1 GS/s real-time sampling and 10 GS/s  repetitive sampling. 
    64 M/Sample buffer size.

    2 x 150 MHz oscilloscope probes (x1/x10) included.

    The PicoScope 2207B is a 70MHz 2-channel oscilloscope that also features built-in spectrum analysis, function/arbitrary waveform generation and serial bus analysis. Sampling at a maximum of 1GSa/s, the 2207B has a buffer memory of 64Msamples and a sophisticated 1MHz AWG signal generator. 15 automatic measurements are available in scope mode and another 11 in spectrum mode. Serial decoding (normally an extra cost on benchtop scopes) is included free for SPI, I2C, FlexRay, CANbus, LINbus, ARINC, and others.  The PicoScope 2207B delivers terrific value for money, with excellent waveform visualization and measurement, as well as fast waveform update rates, giving the performance needed for advanced analysis of waveforms, including serial decoding and frequency plots.

    Introducing the PicoScope 2000 Series
    The PicoScope 2000 Series offers you a choice of 2- and 4-channel oscilloscopes, plus mixed-signal oscilloscopes (MSOs) with 2 analog + 16 digital inputs. All models feature spectrum analyzers, function generators, arbitrary waveform generators and serial bus analyzers, and the MSO models also function as logic analyzers.
    The PicoScope 2000A models all deliver unbeatable value for money, with excellent waveform visualization and measurement to 25 MHz for a range of analog and digital electronic and embedded system applications. They are ideal for education, hobby and field service use.
    The PicoScope 2000B models have the added benefits of deep memory (up to 128 MS), higher bandwidth (up to 100 MHz) and faster waveform update rates, giving you the performance you need to carry out advanced analysis of your waveform, including serial decoding and plotting frequency against time.

    Advanced oscilloscope display

    The PicoScope 6 software takes advantage of the display size and resolution and processing power of your PC – in this case displaying four analog signals, a zoomed view of two of the signals (undergoing serial decoding), and a spectrum view of a third, all at the same time. Unlike a conventional benchtop oscilloscope, the size of the display is limited only by the size of your computer monitor. The software is also easy to use on touch-screen devices – you can pinch to zoom and drag to scroll.

    Powerful, portable and super-small
    The PicoScope 2000 Series oscilloscopes are compact enough to fit easily into your laptop bag along with all their probes and leads. These modern alternatives to bulky benchtop devices are ideal for a wide range of applications including design, test, education, service, monitoring, fault-finding and repair and are perfect for engineers on the move.

    Fast sampling
    The PicoScope 2000 Series oscilloscopes provide fast real-time sampling rates of up to 1 GS/s on the analog channels: this represents a timing resolution of 1 ns.
    For repetitive analog signals, equivalent-time sampling (ETS) mode can boost the maximum effective sampling rate up to 10 GS/s, allowing even finer resolution down to 100 ps. All scopes support pre-trigger and post-trigger capture using the full memory depth.

    High signal integrity
    Here at Pico Technology, we’re proud of the dynamic performance of our products. Careful front-end design and shielding reduce noise, crosstalk and harmonic distortion. Decades of oscilloscope design experience can be seen in improved pulse response and bandwidth flatness.
    The result is simple: when you probe a circuit, you can trust in the waveform you see on the screen.

    High-end features as standard
    Buying a PicoScope is not like making a purchase from other oscilloscope companies, where increased functionality can considerably raise the price. PicoScopes are all-inclusive instruments, with no need for expensive upgrades to unlock the hardware. Other advanced features such as resolution enhancement, mask limit testing, serial decoding, advanced triggering, automatic measurements, math channels (including the ability to plot frequency and duty cycle against time), XY mode and segmented memory are all included in the price.

    USB connectivity
    The USB connection makes printing, copying, saving, and emailing your data from the field quick and easy. The high-speed USB interface allows fast data transfer, while USB powering removes the need to carry around a bulky external power supply.

    The PicoScope software offers a breadth of advanced features via a user-friendly interface. As well as the standard Windows installation, PicoScope Beta software also works effectively on Linux and Mac operating systems, giving you the freedom to choose which platform you operate your PicoScope from.

    Unique commitment to product support
    Your PicoScope gets better the longer you use it, thanks to the regular free updates we supply for both the PC software and the oscilloscope firmware throughout the life of the product: the performance and functionality of the scope both keep improving, without you paying a penny more than the purchase price.
    This level of support, combined with the personal service provided by our technical and sales support teams, is reflected in the consistently good feedback we get from users of our products, many of whom have gone on to be regular customers.

    PicoScope 6 software
    The PicoScope software display can be as simple or as detailed as you need. Begin with a single view of one channel, and then expand the display to include up to four live channels, plus math channels and reference waveforms.

    PicoScope 6 software with mixed digital and analog signals
    The flexibility of the PicoScope 6 software interface allows high-resolution viewing of all analog and digital channels at once, along with math channels and reference waveforms. You can use the whole of your PC’s display to view the waveforms, ensuring you never miss a detail again.

    Arbitrary waveform and function generators
    All PicoScope 2000 Series oscilloscopes have a built-in function generator and arbitrary waveform generator (AWG). The function generator can produce sine, square, triangle and DC level waveforms, and many more besides, while the AWG allows you to import waveforms from data files or create and modify them using the built-in graphical AWG editor.
    As well as level, offset and frequency controls, advanced options allow you to sweep over a range of frequencies. Combined with the advanced spectrum mode, with options including peak hold, averaging and linear/log axes, this creates a powerful tool for testing amplifier and filter responses.

    Digital triggering
    Most digital oscilloscopes still use an analog trigger architecture based on comparators. This can cause time and amplitude errors that cannot always be calibrated out. The use of comparators often limits the trigger sensitivity at high bandwidths and can also create a long trigger rearm delay.
    For 25 years, Pico Technology has been pioneering the use of full digital triggering using the actual digitized data. This eliminates trigger errors and allows our oscilloscopes to trigger on the smallest signals, even at the full bandwidth. All triggering is digital, resulting in a threshold resolution equal to the digitizing resolution, with programmable hysteresis and optimal waveform stability.
    The reduced rearm delay provided by digital triggering, together with segmented memory, allows the capture of events that happen in rapid sequence. Rapid triggering, available on most models, can capture a new waveform every 1 or 2 microseconds, depending on the model, at the fastest timebase, until the buffer is full. The mask limit testing function helps to detect waveforms that fail to meet your specifications.
    As well as the standard range of triggers found on most oscilloscopes, the PicoScope 2000 Series offers one of the best selections of advanced triggers available. These include pulse width, window and dropout triggers to help you find and capture your signal quickly.

    Color persistence modes
    Advanced display modes allow you to see old and new data superimposed, with new data in a brighter color or shade. This makes it easy to see glitches and dropouts and to estimate their relative frequency. Choose between analog persistence, digital color and fast display modes or create your own custom rules.

    The PicoScope 2000 Series’ use of hardware acceleration means that, in Fast Persistence mode, waveform update rates of up to 80000 waveforms per second can be achieved (model-dependent), overlaying them all with color-coding or intensity-grading to show which areas are stable and which are intermittent. Faults that previously took minutes to find now appear within seconds.

    Spectrum analyzer
    With a click of a button, you can open a new window to display a spectrum plot of selected channels up to the bandwidth of the oscilloscope. A comprehensive range of settings gives you control over the number of spectrum bands, window types and display modes.
    PicoScope software allows you to display multiple spectrum views with different channel selections and zoom factors, and see these alongside time-domain waveforms of the same data. A comprehensive set of automatic frequency-domain measurements can be added to the display, including THD, THD+N, SINAD, SNR and IMD. You can even use the AWG and spectrum mode together to perform swept scalar network analysis.

    Custom probe settings
    The custom probes menu allows you to correct for gain, attenuation, offsets and nonlinearities of probes and transducers, or convert your waveform data to different units such as current, scaled voltage, temperature, pressure, power or dB. Definitions can be saved to disk for later use. Definitions for standard Pico Technology oscilloscope probes are built in, and you can also create your own using linear scaling or even an interpolated data table.

    Automatic measurements
    PicoScope allows you to automatically display a table of calculated measurements for troubleshooting and analysis. Using the built-in measurement statistics you can see the average, standard deviation, maximum and minimum of each measurement as well as the live value.
    You can add as many measurements as you need on each view - 15 different measurements are available in scope mode, and 11 in spectrum mode. For information on these measurements, see Automatic Measurements in the Specifications table.

    Serial decoding
    The PicoScope 2000 Series oscilloscopes include serial decoding capability as standard. Display the decoded data in the format of your choice: as a graph, in a table, or both at once.

    • Graph format shows the decoded data beneath the waveform on a common time axis, with error frames marked in red. You can zoom in on these frames to investigate noise or distortion. The data packets are broken down into their component fields, making it easier than ever to locate and identify problems signals, and each packet field is assigned a different color: in the CAN bus example below, the address is colored orange, the DLC green and the data content indigo. Color coding is available in PicoScope 6.12 or later, available for download from www.microtec.dk
    • Table format shows a list of the decoded frames, including the data and all flags and identifiers. You can set up filtering conditions to display only the frames you are interested in, search for frames with specified properties, or define a start pattern to signal when the program should list the data.

    It is also possible to link decoded numeric data to user-defined text strings, for ease of reading.

    With the PicoScope 2000 Series, you can decode up to 15 serial protocols, including 1-Wire, CAN, I2 C, I2 S, LIN, SENT, SPI and UART/RS- 232, depending on the bandwidth and sampling rate of the oscilloscope model. Please see the specification table for the full list.

    PicoScope also includes options to import and export the decoded data using a Microsoft Excel spreadsheet.

    Waveform buffer and navigator
    Ever spotted a glitch on a waveform, but by the time you’ve stopped the scope it’s gone? With PicoScope you no longer need to worry about missing glitches or other transient events. PicoScope can store the last ten thousand waveforms in its circular waveform buffer.
    The buffer navigator provides an efficient way of navigating and searching through waveforms, effectively letting you turn back time. Tools such as mask limit testing can also be used to scan through each waveform in the buffer looking for mask violations.

    Mask limit testing
    PicoScope allows you to draw a mask around any signal with user-defined tolerances. This has been designed specifically for production and debugging environments, enabling you to compare signals. Simply capture a known good signal, draw a mask around it, and then attach the system under test. PicoScope will capture any intermittent glitches and can show a failure count and other statistics in the Measurements window.
    The numerical and graphical mask editors can be used separately or in combination, allowing you to enter accurate mask specifications, modify existing masks, and import and export masks as files.

    High-speed data acquisition and digitizing
    The supplied drivers and software development kit (SDK) allow you to both write your own software and interface to popular third-party software packages such as National Instruments LabVIEW and MathWorks MATLAB.
    The drivers support data streaming, a mode that captures gap-free continuous data over the USB port directly to the PC’s RAM or hard disk at rates of up to 1 MS/s (A models) or 9.6 MS/s (B models), so you are not limited by the size of the scope’s buffer memory. Sampling rates in streaming mode are subject to PC specifications and application loading.
    Beta drivers are also available for use with Raspberry Pi, BeagleBone Black, and similar ARM-powered platforms. These drivers enable you to control your PicoScope using these small, single-board Linux computers.

    Math channels
    With PicoScope 6 you can perform a variety of mathematical calculations on your input signals and reference waveforms.
    Use the built-in list for simple functions such as add and invert, or open the wizard and create complex functions involving trigonometry, exponentials, logarithms, statistics, integrals and derivatives.

    Plot frequency against time with PicoScope 6
    All oscilloscopes can measure the frequency of a waveform, but often you need to know how that frequency changes over time, which is a difficult measurement to make.
    The freq math function can do exactly this: in the example on the right, the top waveform’s frequency is being modulated by a ramp function, as plotted in the bottom waveform.
    There is an additional math function to plot duty cycle in a similar way.

    Model PicoScope
    Bandwidth 10 MHz 25 MHz 50 MHz 70 MHz 100 MHz
    2 channel 2204A 2205A   2206B   2207B 2208B
    4 channel     2405A   2406B 2407B 2408B
    2 channel MSO     2205A MSO   2206B MSO 2207B MSO 2208B MSO
    Oscilloscope — vertical (analog inputs)
    Bandwidth 10 MHz 25 MHz 50 MHz 70 MHz 100 MHz
    Rise time (calculated) 35 ns 14 ns 7 ns 5 ns 3.5 ns
    Vertical resolution 8 bits
    Enhanced vertical resolution Up to 12 bits
    Input ranges ±50 mV, ±100 mV, ±200 mV, ±500 mV, ±1 V, ±2 V, ±5 V, ±10 V, ±20 V ±20 mV, ±50 mV, ±100 mV, ±200 mV, ±500 mV, ±1 V, ±2 V, ±5 V, ±10 V, ±20 V
    Input sensitivity
    (10 vertical divisions)
    10 mV/div to 4 V/div 4 mV/div to 4 V/div
    Input coupling AC / DC
    Input connector BNC(f)
    Input characteristics 1 MΩ ± 1% ∥ 14 pF ± 2 pF 1 MΩ ± 1% ∥ 16 pF ± 1 pF
    Analog offset range
    (vertical position adjustment)
    None ±250 mV (20 mV to 200 mV ranges)
    ±2.5 V (500 mV to 2 V ranges)
    ±25 V (5 V to 20 V ranges)
    Analog offset control accuracy N/A ±1% of offset setting, additional to basic DC accuracy
    DC accuracy ±3% of full scale ±200 μV
    Overvoltage protection ±100 V (DC + AC peak)
    Oscilloscope — vertical (digital inputs, MSOs only)
    Input channels 16 channels (2 ports of 8 channels each)
    Input connectors 2.54 mm pitch, 10 x 2 way connector
    Maximum input frequency 100 MHz (200 Mb/s)
    Minimum detectable pulse width 5 ns
    Input impedance (with TA136 cable) 200 kΩ ±2% ∥ 8 pF ±2 pF
    Input dynamic range ±20 V
    Digital threshold range ±5 V
    Overvoltage protection ±50 V
    Threshold grouping Two independent threshold controls: Port 0: D0 to D7, Port 1: D8 to D15
    Threshold selection TTL, CMOS, ECL, PECL, user-defined
    Port threshold accuracy ±350 mV (inclusive of hysteresis)
    Hysteresis < ±250 mV
    Minimum input voltage swing 500 mV pk-pk
    Channel-to-channel skew 2 ns typical
    Minimum input slew rate 10 V/µs
    Maximum sampling rate (real-time)* 100 MS/s 200 MS/s 500 MS/s 1 GS/s
    Equivalent sampling rate (ETS mode) 2 GS/s 4 GS/s 5 GS/s 10 GS/s
    Maximum sampling rate (USB streaming) 1 MS/s 1 MS/s 9.6 MS/s
    Shortest timebase 10 ns/div 5 ns/div 2 ns/div 1 ns/div
    Longest timebase 5000 s/div (approx 14 hours per waveform in chart recorder view)
    Buffer memory (block mode)* 8 kS 16 kS 48 kS 32 MS 64 MS 128 MS
    Buffer memory (USB streaming mode) 100 MS (shared between active channels)
    Waveform buffers 10 000
    Maximum waveforms per second 2000 80 000
    Initial timebase accuracy ±100 ppm ±50 ppm ±5ppm / year
    Sample jitter 30 ps RMS typical 3 ps RMS typical
    ADC sampling Simultaneous Simultaneous

    * Maximum sampling rate and buffer memory are shared between active channels. On MSO models each group of 8 inputs counts as a channel.  Maximum sampling rate on MSO digital channels is 500 MS/s.

    Dynamic performance
    Crosstalk (full bandwidth, equal ranges) Better than 200:1 Better than 300:1
    Harmonic distortion < –50 dB at 100 kHz, full-scale input, typical
    SFDR (100 kHz, full-scale input, typical) > 52 dB ±20 mV range: > 44 dB
    ±50 mV range and higher: > 52 dB
    Noise < 150 μV RMS
    (±50 mV range)
    < 220 μV RMS
    (±20 mV range)
    < 300 μV RMS
    (±20 mV range)
    Bandwidth flatness (+0.3 dB, –3 dB) from DC to full bandwidth
    Sources Ch A, Ch B, Ch C, Ch D. Any MSO digital channel
    Trigger modes None, auto, repeat, single None, auto, repeat, single, rapid (segmented memory)
    Advanced triggers Edge, window, pulse width, window pulse
    width, dropout, window dropout, interval,
    Edge, window, pulse width, window pulse width, dropout,
    window dropout, interval, runt pulse, logic
    Trigger types, ETS Rising or falling edge Rising or falling edge (available on Ch A only)
    Trigger sensitivity, real-time Digital triggering provides 1 LSB accuracy up to full bandwidth
    Trigger sensitivity, ETS 10 mV p-p, typical, at full bandwidth
    Maximum pre-trigger capture 100% of capture size
    Maximum post-trigger delay 4 billion samples
    Trigger rearm time in rapid trigger mode N/A < 2 μs on fastest
    < 1 μs on fastest timebase
    Max. waveforms in rapid trigger mode N/A 96 10 000
    Function generator
    Standard output signals Sine, square, triangle, DC voltage, ramp, sinc, Gaussian, half-sine
    Pseudorandom output signals None White noise, PRBS
    Standard signal frequency DC to 100 kHz DC to 1 MHz
    Sweep modes Up, down, dual with selectable start/stop frequencies and increments
    Triggering None Free-run or up to 1 billion waveform cycles or frequency sweeps.
    Triggered from scope trigger or manually.
    Output frequency accuracy Oscilloscope timebase accuracy ± output frequency resolution
    Output frequency resolution < 0.02 Hz < 0.01 Hz
    Output voltage range ±2 V
    Output adjustments Any amplitude and offset within ±2 V range
    Amplitude flatness (typical) < 1 dB to 100 kHz < 0.5 dB to 1 MHz
    DC accuracy ±1% of full scale
    SFDR (typical) > 55 dB at 1 kHz full-scale sine wave > 60 dB at 10 kHz full-scale sine wave
    Output characteristics Front panel BNC, 600 Ω output impedance
    Overvoltage protection ±20 V
    Arbitrary waveform generator
    Update rate 1.548 MHz 20 MHz
    Buffer size 4 kS 8 kS 32 kS
    Resolution 12 bits
    Bandwidth > 100 kHz > 1 MHz
    Rise time (10% to 90%) < 2 μs < 120 ns
    Spectrum analyzer
    Frequency range DC to analog bandwidth of oscilloscope
    Display modes Magnitude, average, peak hold
    Windowing functions Rectangular, Gaussian, triangular, Blackman, Blackman-Harris, Hamming, Hann, flat-top
    Number of FFT points Selectable from 128 to half available buffer memory in powers of 2, up to a maximum of 1 048 576 points
    Math channels and Software filters
    Functions −x, x+y, x−y, x*y, x/y, x^y, sqrt, exp, ln, log, abs, norm, sign, sin, cos, tan, arcsin, arccos, arctan, sinh, cosh, tanh, freq, derivative, integral, min, max, average, peak, delay, duty
    Software filters Highpass, lowpass, bandpass, bandstop
    Operands A, B (input channels), C, D (input channels, 4-channel models only), T (time), reference waveforms, constants, pi, digital channels (MSO models only)
    Automatic measurements
    Scope mode AC RMS, true RMS, frequency, cycle time, duty cycle, DC average, falling rate, rising rate, low pulse width, high pulse width, fall time, rise time, minimum, maximum, peak to peak
    Spectrum mode Frequency at peak, amplitude at peak, THD dB, SNR, SINAD, SFDR,
    total power, average amplitude at peak, THD %, THD+N, IMD
    Statistics Minimum, maximum, average and standard deviation
    Serial decoding
    Protocols 1-Wire, ARINC 429, CAN, DCC, DMX512, FlexRay, Ethernet 10Base-T, USB 1.1, I²C, I²S, LIN, PS/2, SPI, SENT, UART/RS-232 (subject to bandwidth and sampling rate of chosen oscilloscope model)
    Mask limit testing
    Mask generation Numeric (automatic) or Graphical (manual)
    Statistics Pass/fail, failure count, total count
    Available actions on mask fail Beep, play sound, stop capture, save waveform, trigger signal generator / AWG, run executable
    Interpolation Linear or sin(x)/x
    Persistence modes Digital color, analog intensity, custom, fast or none
    SDK / API details and specifications for customers writing their own software
    Supplied drivers 32 and 64-bit drivers for Windows 7, 8 and 10
    Linux drivers
    Mac OS X drivers
    Example code C, C#, Excel VBA, VB.NET, LabVIEW, MATLAB
    Maximum USB streaming sampling rate* 1 MS/s 5 MS/s 31 MS/s
    Buffer memory in USB streaming mode* Limited only by PC
    Segmented memory buffers* N/A 96 128000 256000 512000

    * These specifications apply when using the drivers / writing your own software. Refer to Horizontal section above when using PicoScope software

    Package contents PicoScope 2000 series oscilloscope
    2 or 4 switchable 10:1/1:1 oscilloscope probes (except for PicoScope 2204A / 2205A when purchased without probes)
    TA136 digital cable (MSOs only)
    2 × TA139 pack of 10 logic test clips (MSOs only)
    USB cable
    Software and reference CD
    Quick start guide
    PC connectivity USB 2.0 (USB 3.0/3.1 compatible).
    Power requirements Powered from USB port
    (including connectors and feet)
    142 x 92 x 18.8 mm 130 x 104 x 18.8 mm
    Weight < 0.2 kg (7 oz)
    Temperature range, operating 0 °C to 50 °C
    Temperature range, operating, for
    stated accuracy
    15 °C to 30 °C
    Temperature range, storage –20 °C to +60 °C
    Humidity range, operating 5% to 80% RH non-condensing
    Humidity range, storage 5% to 95% RH non-condensing
    Altitude range up to 2000 m
    Pollution degree 2
    Safety approvals Designed to EN 61010-1:2010
    Environmental approvals RoHS, WEEE
    EMC approvals Tested to meet EN61326-1:2013 and FCC Part 15 Subpart B
    Software included PicoScope 6 for Microsoft Windows 7, 8 and 10
    32-bit and 64-bit SDK for Windows 7, 8 and 10
    32-bit and 64-bit example programs (C, Microsoft Excel VBA, LabVIEW)
    Free software available for download PicoScope 6 (beta) for Linux and OS X. Please note that the Linux and OS X beta versions of PicoScope do not yet have mask limit test or math channel functions.
    SDK (beta) for Linux and OS X
    Languages supported Simplified Chinese, Czech, Danish, Dutch, English, Finnish, French, German, Greek, Hungarian, Italian, Japanese, Korean, Norwegian, Polish, Portuguese, Romanian, Russian, Spanish, Swedish, Turkish