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SRS FS740 — GPS Time and Frequency System

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  • SRS FS740 — GPS Time and Frequency System
  • SRS FS740 — GPS Time and Frequency System
  • SRS FS740 — GPS Time and Frequency System
  • FS740 Freq. Stability Unlocked to GPS
  • FS740 Freq. Stability  Locked to GPS
  • FS740 Antenna

SRS FS740 — GPS Time and Frequency System

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Availability: In stock

Excl. VAT: £3,031.00 Incl. VAT: £3,637.20
Product Code: FS740
Manufacturer: Stanford Research Systems

  • GPS disciplined 10 MHz reference 

  • 1 × 10-13 long term stability

  • Time tag events to UTC or GPS

  • Sine, square, triangle, IRIG-B output

  • Frequency counter, distribution amplifiers

  • Ethernet and RS-232 computer interfaces


 

SRS FS740 GPS Time and Frequency System

The Stanford Research Systems FS740 provides a 10 MHz frequency reference which is disciplined by GPS with a long term stability of better than 1 × 10-13. The instrument can also time tag external events with respect to UTC or GPS and measure the frequency of user inputs. The instrument has DDS synthesized frequency outputs, adjustable rate (and width) pulse outputs, and an AUX output for arbitrary waveforms including an IRIGB timecode output. 

Standard, OCXO, or Rubidium Timebase

The standard timebase provides 1 × 10-9 short term frequency stability and phase noise of less than -100 dBc/Hz at 10 Hz offset. An optional OCXO (ovenized crystal oscillator) timebase provides 1 × 10-11 short term frequency stability and phase noise of less than -130 dBc/Hz at 10 Hz offset. An optional rubidium timebase provides 1 × 10-12 short term frequency stability, phase noise of less than -130 dBc/Hz at 10 Hz offset, and a long term holdover (lost GPS signal) of better than 1 µs/day.

Both optional timebases (OCXO or rubidium) provide a dramatic improvement in the holdover characteristics, a 30 dB reduction in the phase noise and a tenfold reduction in the TDEV. There are some users who would not need this performance improvement. For example, users who only need time tags with 1µs accuracy or frequency measurements with 1:108 accuracy could use the standard timebase.


GPS Receiver

The SRS FS740 provides bias for a remote active GPS antenna. The unit’s GPS receiver tracks up to 12 satellites, will automatically survey and fix its position, then use all received signals to optimize its timing solution. The SRS FS740 time-tags the 1 pps output from the receiver, corrects the result for the receiver’s sawtooth error, then phase locks the timebase to the GPS 1 pps with an adjustable time constant between 1 minute and 10 hours. The TDEV (rms timing deviation) between two instruments is a few nanoseconds. 

If the GPS signal is lost, the timebase is left at the last locked frequency value. The timebase will age or drift in frequency by up to ±2 ppm (for the standard timebase), ±0.05 ppm/year and ±0.002 ppm (0 to 45°C) for the OCXO, and ±0.001 ppm/year and ±0.0001 ppm (0 to 45°C) for the rubidium timebase.

GNSS Antennas

You may choose to purchase a GPS antenna from SRS, or a third party, or use an existing GPS antenna at their facility. SRS timing receivers require a net gain (after cable losses) of +20 dBi to +32 dBi, which is a very common level from a variety of available active antennas and typical cable lengths. The antenna input to SRS timing receivers have a female BNC connector, provide +5 V bias, and have a 50 O input impedance.

SRS offers two antenna solutions, both of which have LNAs. All systems components have a 50 O characteristic impedance. For antenna details click here.

Graphical User Interface

A GUI (graphical user interface) allows the user to configure the instrument and see the results of time and frequency measurements. The instrument can be configured in one of three modes: There are two user inputs (one on the front, one on the rear panel) for frequency and time tag events. The inputs have adjustable thresholds and slopes. Frequencies are measured with a precision of 1 × 10-11 in 1 s, 

1 × 10-12 in 10 s, and 1 × 10-13 in 100 s. Time tags are reported with 1 ps resolution which is comparable to the short term stability of the OCXO and rubidium timebases. Time tags will have an error of about 10 ns rms with respect to UTC or GPS time.


Front and Rear Panel

The SRS FS740 has a rear panel low phase noise (-130 dBc/Hz at 10 Hz offset) 10 MHz sine output with an amplitude of 1 Vrms. Up to 15 additional copies of the 10MHz output are available via optional rear panel outputs.

The SRS FS740 has front and rear panel SINE outputs which provide sine outputs from 1 µHz to 30.1 MHz with 1 µHz resolution, or a fixed 100 MHz, with adjustable amplitude from 100 mV to 1.2 V rms. Up to 15 additional copies of the SINE outputs are available via optional rear panel outputs.

The SRS FS740 has front and rear panel PULSE outputs which can provide low jitter (<5 ps,rms) pulses from 1 µHz to 30.1 MHz. The PULSE outputs have adjustable phase with respect to UTC and the pulse width can be set as narrow as 5 ns, or as wide as the entire pulse period minus 5 ns, with 10 ps resolution. Up to 15 additional copies of the PULSE outputs are available via optional rear panel outputs.
The SRS FS740 has front and rear panel AUX output which can generate standard or arbitrary waveforms (sine, ramp, triangle, etc.) The AUX output can also provide an IRIG-B timecode output. Both width coded pulses and amplitude modulated sine waves (with carrier frequencies from 100 Hz to 1 MHz) are available for the IRIG-B outputs. Up to 15 additional copies of the AUX output are available via optional rear panel outputs.

A rear panel alarm relay is set if power is lost or under user defined conditions including: timebase fault, loss of GPS reception, or any failure to maintain phase lock between the timebase and GPS. The relay has both normally open and closed outputs.

Distribution Amplifiers

Optional distribution amplifiers, each providing six additional rear panel outputs for the 10 MHz, SINE, PULSE, AUX or IRIG-B outputs, can be installed. Up to three distribution amplifiers can be installed and configured from the front panel. Each output has its own driver which provides high isolation between outputs.

Additional Information

FS740 GPS Time and Frequency System

Standard TCXO Timebase

Oscillator type

Oven controlled, 3rd OT, AT-cut crystal

Stability

<2 × 10-6 (20 to 30 °C)

Aging (undisciplined to GPS)

<5 ppm/year

OCXO Timebase

Oscillator type

Oven controlled, 3rd OT, SC-cut crystal

Stability

<1 × 10-6 (20 to 30 °C)

Aging (undisciplined to GPS)

<0.2 ppm/year

Rubidium Timebase

Oscillator type

Oven controlled, 3rd OT, SC-cut crystal

Physics package

Rubidium vapor frequency discriminator

Stability

<1 × 10-10 (20 to 30 °C)

Aging (undisciplined to GPS)

<0.0005 ppm/year

GPS Receiver

Time to satelite acquisition

Less than 1 minute (typ.)

Time to acquire almanac

Approximately 15 minutes when continuously tracking satellites

Optimized for static applications

Over determined clock mode enables receiver to use all satellites for timing

Accuracy of UTC

<100 ns

Time wander

<15 ns rms (in over determined clock mode)

Antenna delay correction range

±0.1 s

Sine Output (50 Ω load)

Frequency range

1 mHz to 30.1 MHz

Frequency resolution

1 µHz

Frequency error

<10 pHz + timebase error × FC

Phase settability

1 mDeg

Phase accuracy

<1 ns (to internal  refeence)

Amplitude

10 mVpp to 1.414 Vpp

Amplitude resolution

<1 %

Amplitude accuracy

±5 %

Harmonics

<-40 dBc

Spurious

<-70 dBc

Output coupling

DC, 50 Ω ±2 %

User load

50 Ω

Reverse protection

±5 VDC

Aux Output (50 Ω load)

Output options

Sine, Triangle, Square, 100 MHz, AM IRIG-B

Frequency range

1 mHz to 10 MHz (sine)
1 mHz to 1 MHz (triangle or square)
100 MHz (100 MHz sine)
1 kHz (AM IRIG-B)

Frequency resolution

1 µHz

Frequency error

<10 pHz + timebase error × FC

Phase settability

1 mDeg (cannot adjust phase of 100 MHz sine output)

Amplitude (sine, triangle, square)

10 mVpp to 1.414 Vpp

Amplitude (100 MHz)

2.75 dBm ±0.5 dBm

Amplitude resolution

<1 %

Amplitude accuracy

±5 %

Harmonics

<-40 dBc

Spurious

<-70 dBc

Output coupling

DC, 50 Ω ±2 %

User load

50 Ω

Reverse protection

±5 VDC

Pulse Output

Output options

Period/width, Freq/duty, Pulse IRIG-B

Period

40 ns to 1000 s

Width

5 ns to (Period - 5 ns)

Period/width resolution

1 ps

Frequency range

1 mHz to 25 MHz

Frequency resolution

1 µHz

Frequency error

<10 pHz + timebase error × FC

Jitter

<50 ps rms

Level

+5 V CMOS logic

Transition time

<2 ns

Source impedance

50 Ω

Time and Frequency Input

Time tag resolution

1 ps

Time tag jitter (rms)

<50 ps

Frequency resolution

1 µHz

Measurement stability (1 s gate)

<5 × 10-12 (synchronous with fast averaging enabled)
<5 × 10-11 (otherwise)

Computer Interfaces (standard)

Ethernet (LAN)

10/100 Base-T. TCP/IP & DHCP default

RS-232

4.8k-115.2k baud, RTS/CTS flow

General

AC power

90 to 264 VAC, 47 to 63 Hz with PFC, 90 W

EMI Compliance

FCC Part 15 (Class B), CISPR-22 (Class B)

Dimensions

8.5" × 3.5" × 13" (WHL)

Weight

10 lbs.

Warranty

One year parts and labor on defects in materials and workmanship

 

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