PXF3303-PicoScope-6000-Series

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PicoScope-6000-Series


型号: PXF3303


简介:PicoScope performance and reliabilityWith over 20 years’ experience in the test and measurement industry, we know what’s important in a new oscilloscope. The PicoScope 6000 Series scopes give you the best value for money of any oscilloscope, with outstanding bandwidth, sampling rate and memory depth specifications. These features are backed up by advanced software optimized with the help of fe...
品牌 pico pico
产地英国
型号PXF3303
折扣其他电询

PicoScope performance and reliability With over 20 years’ experience in the test and measurement industry, we know what’s important in a new oscilloscope. The PicoScope 6000 Series scopes give you the best value for money of any oscilloscope, with outstanding bandwidth, sampling rate and memory depth specifications. These features are backed up by advanced software optimized with the help of feedback from our customers.

High bandwidth, high sampling rate With 250 MHz to 500 MHz analog bandwidths complemented by a real-time sampling rate of 5 GS/s, the PicoScope 6000 Series scopes can display single-shot pulses with 200 ps time resolution. Equivalent time sampling (ETS) mode boosts the maximum

The PicoScope 6000 Series gives you the deepest buffer memory available as standard on any oscilloscope at any price. The SuperSpeed USB 3.0 interface ensures that the display is smooth and responsive even with long captures. Other oscilloscopes have high maximum sampling rates, but without deep memory they cannot sustain these rates on long timebases. The 2-gigasample buffer on the PicoScope 6404D can hold two 200 ms captures at the maximum sampling rate of 5 GS/s. To help manage all this data, PicoScope can zoom up to 100 million times using a choice of two zoom methods. There are zoom buttons as well as an overview window that lets you zoom and reposition the display by simply dragging with the mouse.

To help you find you way around the buffer memory, you can divide it into as many as 10,000 individually triggered segments. Use the visual buffer navigator to scan through the segments, or set up a mask to filter out the waveforms of interest.

Custom probe settings The custom probes menu allows you to correct for gain, attenuation, offsets and nonlinearities of probes and transducers, or convert to different measurement units. Definitions for standard Pico-supplied probes are built in, but you can also create your own using linear scaling or even an interpolated data table.

Arbitrary waveform and function generator

import arbitrary waveforms from data files or create and modify them using the built-in graphical AWG editor.

Spectrum analyzer With the click of a button, you can open a new window to display a spectrum plot of selected channels up to the full bandwidth of the oscilloscope. The spectrum view can optionally be displayed together with a time-domain view. A comprehensive range of settings give you control over the number of spectrum bands, window types and display modes.

Color persistence modes

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 or custom display modes.

Mask limit testing

This feature is designed for production and debugging environments. Capture a signal from a known working system, and PicoScope will draw a mask around it with your specified vertical and horizontal tolerances. Connect the system under test, and PicoScope will highlight any parts of the waveform that fall outside the mask area. The highlighted details persist on the display, so the scope can catch intermittent glitches even while your attention is elsewhere. The measurements window counts the number of failures, and can display other measurements and statistics at the same time.

The numerical and graphical mask editors (both shown below) can be used separately

or in combination, allowing you to enter accurate mask specifications or modify existing masks. You can import and export masks as files.

High-speed data acquisition

The drivers and software development kit supplied allow you to write your own software or interface to popular third-party software packages. If the 2 GS buffer memory of the PicoScope 6404D isn’t enough, the drivers support data streaming, a mode that captures gap-free continuous data over the USB 3.0 port directly to the PC’s RAM at over 150 MS/s and to solid-state disk at up to 78 MS/s. Rates are subject to PC specifications and application loading.

Serial data decoding

well-suited to serial decoding, with a deep memory buffer that allows them to collect long, uninterrupted sequences of data. This allows the capture of thousands of frames or packets of data over several seconds. The scopes can decode up to four buses simultaneously with independent protocol selection for each input channel.

PicoScope displays the decoded data in the format of your choice: in viewin window, or both at once.

  • In view 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 look for noise or distortion on the waveform.
  • In window 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 that the program will wait for before it lists the data.

Analog and digital low-pass filtering

Each input channel has its own digital low-pass filter with independently adjustable cut-off frequency from 1 Hz to the full

scope bandwidth. This enables you to reject noise on selected channels while viewing high-bandwidth signals on the others.

An additional selectable analog bandwidth limiter on each input channel can be used to reject high frequencies that would otherwise cause aliasing.

Digital triggering Most digital oscilloscopes sold today 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. In 1991 Pico pioneered the use of fully digital triggering using the

actual digitized data. This technique reduces trigger errors and allows our oscilloscopes to trigger on the smallest signals, even at the full bandwidth. Trigger levels and hysteresis can be set with high precision and resolution.

Digital triggering also reduces re-arm delay and this, combined with the segmented memory, allows the triggering and capture of events that happen in rapid sequence. At the fastest timebase you can use rapid triggering to collect 10,000 waveforms in under 10 milliseconds. The mask limit testing function can then scan through these waveforms to highlight any failed waveforms for viewing in the waveform buffer.

Advanced triggers As well as the standard range of triggers found on most oscilloscopes, the PicoScope 6000 Series has a built-in set of advanced triggers to help you capture the data you need.

All triggering is digital, resulting in high threshold resolution with programmable hysteresis and optimal waveform stability.

Maths channels With PicoScope 6 you can perform a variety of mathematical calculations on your input signals. You can calculate the sum, difference, product or inverse, or create your own custom function using standard arithmetic, exponential and trigonometric functions.

Automatic measurements

PicoScope allows you to automatically display a table of calculatemeasurements 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 valueYou can add as many measurements as you need on each view. Eacmeasurement includes statistical parameters showing its variability.

For information on the measurements available in scopand spectrum modes, see Automatic Measurements in theSpecifications table.

High signal integrity

Most oscilloscopes are built down to a price; ours are built up to a specification. Our engineers use careful front-end design and shielding to

reduce noise, crosstalk and harmonic distortion. With decades of oscilloscope experience, we know how to design for optimal pulse response and bandwidth flatness.

Hardware acceleration On some oscilloscopes, enabling deep memory has a penalty: the screen update rate slows down and the controls become unresponsive as the processor struggles to cope with the amount of data. Thanks to the hardware acceleration inside PicoScope deep-memory oscilloscopes, you can collect waveforms containing hundreds of millions of samples while keeping fast screen update rates and a responsive user interface. Dedicated hardware inside the oscilloscope processes multiple streams of data in parallel to construct the waveform that will be displayed on the screen. This is done far faster than any PC processor could manage, and together with USB 3.0 SuperSpeed data transfer eliminates any bottlenecks between the oscilloscope and the PC. For example, the scope may be set to capture 100 000 000 samples but the PicoScope display window may be only 1000 pixels wide. In this case, the scope intelligently compresses the data into 1000 blocks of 100 000 samples each. Unlike simple decimation, which throws away most of the data, PicoScope hardware acceleration guarantees that you see any high-frequency details such as narrow glitches, even when the display is zoomed out.

High-end features as standarBuying a scope from some companies is a bit like buying a carBy the time you have added all the optional extras you needthe price has gone up considerably. With the PicoScope 600Series, high-end features such as mask limit testing, serial decodingadvanced triggering, measurements, math, XY mode, digital

filtering, segmented memory and even a signal generator are alincluded in the priceTo protect your investment, both the PC software and firmware

inside the unit can be updated. We have a long history of providing new features for free as software downloads. Other companies make vague promises about future enhancements but we deliver on our promises year after year. Users of our products reward us by becoming lifelong customers, frequently recommending us to their colleagues.

Probes includeYour PicoScope 6000 Series scope is supplied complete witfour wideband, high-impedance probes. These probes have beedesigned for use with individual models of the PicoScope 600Series and are factory-compensated to match each scope’input characteristics. Each high-quality probe is supplied with a

range of accessories for convenient and accurate high-frequencmeasurementsA comprehensive range of alternative probes is also available.

Probe specifications TA150 TA133

Attenuation 10:1
Resistance at probe tip 10 MΩ
Capacitance at probe tip 9.5 pF
Scope input impedance 1 MΩ
Compatibility PicoScope 6402C/D, PicoScope 6403C/D PicoScope 6404C/D
Bandwidth (3 dB) 350 MHz 500 MHz
Rise time (10% to 90%) 1 ns 700 ps
Compensation range 10 to 25 pF
Safety standard IEC/EN 61010-031
Cable length 1.3 m

Probe accessories included

TA133 and TA150

  • Instruction manual
  • Solid tip 0.5 mm
  • Coding rings, 3 x 4 colors
  • Ground lead 15 cm
  • Ground spring 2.5 mm
  • Trim tool
  • Insulating cap 2.5 mm
  • Sprung hook 2.5 mm

TA133 only

  • Spring tip 0.5 mm
  • Ground blade 2.5 mm
  • 2 self-adhesive copper pads
  • Protection cap 2.5 mm
  • IC caps 0.5 to 1.27 mm pitch
  • PCB adapter kit 2.5 mm
PicoScope 6402C PicoScope 6402D PicoScope 6403C PicoScope 6403D PicoScope 6404C PicoScope 6404D
VERTICAL
Input channels 4, BNC connectors, single-ended
Analog bandwidth (-3 dB)* 250 MHz (200 MHz on ±50 mV range) 350 MHz (250 MHz on ±50 mV range) 500 MHz
Bandwidth limiting 20 MHz, switchable 20 MHz, switchable 25 MHz, switchable
Rise time (10% to 90%, calculated) 1.4 ns (50 mV range 1.8 ns) 1.0 ns (50 mV range 1.4 ns) 0.7 ns (all ranges)
Input ranges (full scale) ±50 mV to ±20V, in 9 ranges (1 MΩ input), ±50 mV to ±5V, in 7 ranges (50 Ω input)
Input sensitivity 10 mV/div to 4 V/div at x1 zoom (1 MΩ input), 10 mV/div to 1 V/div at x1 zoom (50 Ω input)
Input coupling 1 MΩ (AC or DC), 50 Ω (DC only)
Input characteristics 1 MΩ || 15 pF, or 50 Ω ±2% 1 MΩ || 10 pF, or 50 Ω ±2%
Analog offset range ±50 to ±200 mV input ranges: ±0.5 V ±500 mV input range: ±2.5 V ±1 V ″ ±2.5 V ±2 V″ ±2.5 V ±5 V ″ ±20 V (50 Ω: ±0.5 V) ±10 V ″ ±20 V ±20 V ″ ±20 V ±2 V ±10 V (50 Ω: ±5 V) ±10 V (50 Ω: ±4.5 V) ±10 V (50 Ω: ±3.5 V) ±35 V (50 Ω: ±0.5 V) ±30 V ±20 V
DC accuracy 3% of full scale
Overvoltage protection ±100 V to ground (1 MΩ inputs), 5.5 V RMS (50 Ω inputs)

* Stated bandwidth is with supplied probes or at BNC when 50 Ω impedance selected

DYNAMIC PERFORMANCE
Noise 200 μV RMS (50 mV range) 320 μV RMS (50 mV range)
THD –55 dB typical –54 dB typical
SFDR 60 dB typical 55 dB typical
Crosstalk 17 000:1 typical at 20 MHz 1000:1 typical at full bandwidth 5600:1 typical at 20 MHz 560:1 typical at full bandwidth
HORIZONTAL (TIMEBASE)
Timebase ranges 1 ns/div to 5000 s/div (real-time sampling) 50 ps/div to 100 ns/div (equivalent-time sampling / ETS)
Timebase accuracy ±2 ppm
Timebase ageing 1 ppm per year
ACQUISITION
ADC resolution 8 bits (up to 12 bits using software resolution enhancement)
Maximum real-time sampling rate 1 channel 5 GS/s 2 channels 2.5 GS/s** 4 channels 1.25 GS/s
Maximum ETS rate 50 GS/s (any number of channels)
Maximum streaming data rate (PicoScope 6) 10 MS/s
Maximum streaming data rate (SDK) Data transfer > 150 MS/s, streaming to SSD hard drive 78 MS/s (USB 3.0, PC-dependent, subject to application loadings)
Buffer size (shared between active channels) 256 MS 512 MS 512 MS 1 GS 1 GS 2 GS
Buffer size (streaming mode) 100 MS in PicoScope software. Up to available PC memory when using SDK.
Max. buffer segments (using PicoScope 6) 10 000
Max. buffer segments (using SDK) 250 000 500 000 500 000 1 000 000 1 000 000 2 000 000

** To achieve 2.5 GS/s sampling rate in 2-channel mode, use channel A or B and channel C or D.

TRIGGERING
Sources Channels A to D, AUX
Trigger modes None, single, repeat, auto, rapid (segmented memory), ETS
Advanced trigger types (real-time mode) Edge, pulse width, window, window pulse width, dropout, window dropout, level, interval, logic level, runt pulse
Trigger types (ETS mode) Rising edge, falling edge
Trigger sensitivity 1 LSB accuracy up to full bandwidth of scope
Trigger level Adjustable over whole of selected voltage range
Maximum pre-trigger capture 100% of capture size
Maximum post-trigger delay 4 billion samples
Re-arm time Less than 1 μs on fastest timebase
Maximum trigger rate Up to 10,000 waveforms in a 10 ms burst
Trigger timing resolution 1 sample period
AUX TRIGGER INPUT
AUX trigger connector type Rear panel BNC, shared with reference clock input
Trigger types Edge, pulse width, dropout, interval, logic
Input characteristics 50 Ω ±1%, DC coupled
Bandwidth 25 MHz
Threshold range ±1 V
Overvoltage protection ±5 V (DC + AC peak)
REFERENCE CLOCK INPUT (SDK ONLY)
Clock input characteristics 50 Ω, BNC, ±1 V, DC coupled
Frequency range 5, 10, 20, 25 MHz, user-selectable
Connector Rear panel BNC, shared with AUX trigger
Level Adjustable threshold, ±1 V
Overvoltage protection ±5 V

Model selector Have you seen the

PicoScope 6407 Digitizer?

The PicoScope 6407 Digitizer has four 1 GHz inputs and a maximum sampling rate of 5 GS/s.

• PicoScope 6407 Digitizer

Model Bandwidth Buffer size Signal generator Arbitrary waveform generator
PicoScope 6402C 256 MS
PicoScope 6402D 250 MHz 512 MS
PicoScope 6403C 512 MS
PicoScope 6403D 350 MHz 1 GS
PicoScope 6404C 1 GS
PicoScope 6404D 500 MHz 2 GS
Description GBP USD EUR
PP884 PicoScope 6402C 250 MHz Oscilloscope with probes 1 995 3 292 2 414
PP885 PicoScope 6402D 250 MHz Oscilloscope with AWG and probes 2 495 4 117 3 019
PP886 PicoScope 6403C 350 MHz Oscilloscope with probes 2 995 4 942 3 624
PP887 PicoScope 6403D 350 MHz Oscilloscope with AWG and probes 3 495 5 767 4 229
PP888 PicoScope 6404C 500 MHz Oscilloscope with probes 3 995 6 592 4 834
PP889 PicoScope 6404D 500 MHz Oscilloscope with AWG and probes 4 495 7 417 5 439
TA150 Replacement x10 probe for PicoScope 6402C/D & 6403C/D 125 206 151
TA133 Replacement x10 probe for PicoScope 6404C/D 125 206 151
TA065, TA066 and TA067 accessory packs for TA150 and TA133 probes www.picotech.com

Prices are correct at the time of publication. Please contact Pico Technology for the latest prices before ordering.

Headquarters: USA Branch Office: Pico Technology Pico Technology James House 320 Glenwood Blvd Colmworth Business Park Tyler St. Neots Texas 75702 Cambridgeshire United States

PE19 8YP

United Kingdom

• +44(0) 1480 396395 • +1 800 591 2796

• +44 (0) 1480 396296 • +1 620 272 0981

• sales@picotech.com • sales@picotech.com

Product pack contents

  • PicoScope 6000 Series oscilloscope
  • Four factory-compensated probes
  • USB cable
  • Universal mains (AC) power supply
  • Mains lead (power cord)
  • Installation Guide
  • Software and Reference CD
  • Carrying case

Ordering information

Need more bandwidth?

For repetitive signals such as serial data streams, and characterization of cables and backplanes, the PicoScope 9000 Series Sampling Oscilloscopes deliver high specifications at low prices. Choose between the 12 GHz PicoScope 9200 Series and the 20 GHz PicoScope 9300 Series. TDR/TDT and optical models are also available.

• PicoScope 9000 Series

Errors and omissions excepted. Windows is a registered trade mark of Microsoft Corporation in the United States and other countries. Pico Technology and

PicoScope are internationally registered trade marks of Pico Technology Ltd. MM050 2. Copyright © 2011 2013 Pico Technology Ltd. All rights reserved.



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