Used Stanford Research Systems CG635 Synthesized Clock Generator, 2GHz
Synthesized Clock Generator 2GHz

Order #: CG635-USED

Mfg #: CG635-USED

Questions about availability or need help? Contact Us:

(800) 633-0561
$6,993.00

Used Stanford Research Systems CG635 Synthesized Clock Generator, 2GHz

Synthesized Clock Generator 2GHz

Order #: CG635-USED

Mfg #: CG635-USED

$6,993.00

Request a Used Instrument Quote

Have a Question? Speak to a Transcat Expert: 800.264.4059

Used instruments from TranscatTranscat Used Instrument Guarantee
Calibration Certificate Included 6 Month Warranty Unsurpassed Service & Support

Availability: Call for Availability
This product is available for shipping to the United States, Canada, and Puerto Rico only.
This product is available for shipping to the United States, Canada, and Puerto Rico only.
This product is available for shipping to the United States, Canada, and Puerto Rico only.

Product Highlights

  • Clocks from 1 µHz to 2.05 GHz
  • Random jitter less than 1 ps rms
  • 16 digits of frequency resolution
  • 80 ps rise and fall times
  • CMOS, PECL, ECL, LVDS & RS-485
  • Phase control and time modulation
  • PRBS for eye-pattern testing
  • OCXO and rubidium timebase

The CG635 generates extremely stable square wave clocks between 1 µHz and 2.05 GHz. The instrument's high frequency resolution, low jitter, fast transition times, and flexible output levels make it ideal for use in the development and testing of virtually any digital component, system or network.

Clean clocks are critical in systems that use high-speed ADCs or DACs. Spurious clock modulation and jitter create artifacts and noise in acquired signals and in reconstructed waveforms.

The CG635 generates extremely stable square wave clocks between 1 µHz and 2.05 GHz. The instrument's high frequency resolution, low jitter, fast transition times, and flexible output levels make it ideal for use in the development and testing of virtually any digital component, system or network.

Clock and PRBS Signals

Clean clocks are critical in systems that use high-speed ADCs or DACs. Spurious clock modulation and jitter create artifacts and noise in acquired signals and in reconstructed waveforms. Clean clocks are also important in communications systems and networks. Jitter, wander, or frequency offsets can lead to high bit error rates, or to a total loss of synchronization. The CG635 can provide the clean, stable clocks required for the most critical applications.

Output Drivers

The CG635 has several clock outputs. The front-panel Q and -Q outputs provide complementary square waves at standard logic levels (ECL, PECL, LVDS or +7 dBm). The square wave amplitude may also be set from 0.2 V to 1.0 V, with an offset between -2 V and +5 V. These outputs operate from DC to 2.05 GHz, have transition times of 80 ps, a source impedance of 50 Ω, and are intended to drive 50 Ω loads. Output levels double when these outputs are unterminated.

The front-panel CMOS output provides square waves at standard logic levels. The output may also be set to any amplitude from 0.5 V to 6.0 V. The CMOS output has transition times of less than 1 ns and operates up to 250 MHz. It has a 50 Ω source impedance and is intended to drive high impedance loads at the end of any length of 50 Ω coax cable.

Phase Noise

A rear-panel RJ-45 connector provides differential square wave clocks on twisted pairs at RS-485 levels (up to 105 MHz) and LVDS levels (up to 2.05 GHz). This output also provides ±5 VDC power for optional line receivers (CG640 to CG649). The clock outputs have 100 Ω source impedances and are intended to drive shielded CAT-6 cable with 100 Ω terminations. The differential clocks may be used directly by the target system, or with optional line receivers that provide complementary logic outputs on SMA connectors.

Choice of Timebases

The standard crystal timebase has a stability of better than 5 ppm. The CG635's 10 MHz timebase input allows the instrument to be phase-locked to an external 10 MHz reference. The 10 MHz output may be used to lock two CG635s together.

There are two optional timebases. An oven-controlled crystal oscillator (OCXO) provides about 100 times better frequency stability than the standard crystal oscillator. A rubidium frequency source provides about 10,000 times better stability. Either optional timebase will substantially reduce the low-frequency phase noise of the synthesized output.

Phase and Time Modulation

The clock phase can be adjusted with high precision. The phase resolution is one degree for frequencies above 200 MHz, and increases by a factor of ten for each decade below 200 MHz, with a maximum resolution of one nano-degree. This allows clock edges to be positioned with a resolution of better than 14 ps at any frequency between 0.2 Hz and 2.05 GHz.

RF Spectrum of a 100 MHz Clock

The timing of clock edges can be modulated over ±5 ns via a rear-panel time-modulation input. The input has a sensitivity of 1 ns/V and a bandwidth from DC to over 10 kHz, allowing an analog signal to control the phase of the clock output. This feature is very useful for characterizing a system's susceptibility to clock modulation and jitter.

For Every Application

With its exceptionally low phase noise and high frequency resolution, the CG635 replaces RF signal generators in many applications. Front-panel outputs provide square waves up to +7 dBm-ideal for driving RF mixers. Should your application require sine waves, in-line low-pass filters are commercially available to convert the CG635's square wave outputs to low distortion sine wave outputs.

The CG635 can provide a wide range of clean, precise clocks for the most critical timing requirements. The instrument is an essential tool for demonstrating a system's performance with a nearly ideal clock, and for understanding a system's susceptibility to a compromised clock. The CG635 has the frequency range, precision, stability, and jitter-free performance needed to fulfill all your clock requirements.

Win a Generac Generator when purchasing $750 or more from Transcat.Win a Generac Generator when purchasing $750 or more from Transcat.
CG635 Specifications
Frequency
Range DC, 1 µHz to 2.05 GHz
Resolution 16 digits (f &#ge; 10 kHz), 1 pHz (f < 10 kHz)
Accuracy ?f < ±(2 x 10-19 + timebase error) x f
Settling time <30 ms
Timebase (20 °C to 30 °C ambient)
Stability <5 ppm (std. timebase)
<0.01 ppm (opt. 02 OCXO)
<0.0001 ppm (opt. 03 Rb timebase)
Aging <5 ppm/year (std. timebase)
<0.2 ppm/year (opt. 02 OCXO)
<0.0005 ppm/year (opt. 03 Rb timebase)
External input 10 MHz ± 10 ppm, sine >0.5 Vpp, 1 kΩ
Output 10 MHz, 1.41 Vpp sine into 50 Ω
Phase Noise (at 622.08 MHz)
100 Hz offset <-90 dBc/Hz
1 kHz offset <-100 dBc/Hz
10 kHz offset <-100 dBc/Hz
100 kHz offset <-110 dBc/Hz
Jitter and Wander
Jitter (rms) <1 ps (1 kHz to 5 MHz bandwidth)
Wander (p-p) <20 ps (10 s persistence)
Time Modulation (rear-panel input)
Input impedance 1 kΩ
Sensitivity 1 ns/V, ±5 %
Range ±5 ns
Bandwidth DC to greater than 10 kHz
Phase Setting
Range ±720° (max. step size ±360°)
Resolution <14 ps
Slew time <300 ms
Q and -Q Outputs
Outputs Front-panel BNC connectors
Frequency range DC to 2.05 GHz
High level -2.00 V ≤ VHIGH ≤ +5.00 V
Amplitude 200 mV ≤ VAMPL ≤ 1.00 V
(VAMPL ࣕ VHIGH - VLOW)
Level resolution 10 mV
Level error <1 % + 10 mV
Transition time <100 ps (20 % to 80 %)
Symmetry <100 ps departure from nominal 50 %
Source impedance 50 Ω(±1 %)
Load impedance 50 Ω to ground on both outputs
Preset levels PECL, LVDS, +7 dBm, ECL