Brand Name: | SRS |
Model Number: | SG382 SG384 SG386 |
MOQ: | 1 set |
Price: | Negotiation |
Payment Terms: | T/T |
SRS Stanford Research Systems Model SG380 Series RF Signal Generators SG382 SG384 SG386
Description of SRS Stanford Research Systems Model SG382 SG384 SG386 RF Signal Generators
Introducing the new SG380 Series RF Signal Generators—finally, high performance, affordable RF sources.
The SG380 Series RF Signal Generators use a unique, innovative architecture (Rational Approximation Frequency Synthesis) to deliver ultra-high frequency resolution (1 µHz), excellent phase noise, and versatile modulation capabilities (AM, FM, ØM, pulse modulation and sweeps) at a fraction of the cost of competing designs.
The SG380 Series RF Signal Generators use a unique, innovative architecture (Rational Approximation Frequency Synthesis) to deliver ultra-high frequency resolution (1 µHz), excellent phase noise, and versatile modulation capabilities (AM, FM, ØM, pulse modulation and sweeps) at a fraction of the cost of competing designs. The standard models produce sine waves from DC to 2.025 GHz (SG382), 4.05 GHz (SG384) and 6.075 GHz (SG386).
The standard models produce sine waves from DC to 2.025 GHz (SG382), 4.05 GHz (SG384) and 6.075 GHz (SG386). There is an optional frequency doubler (Opt. 02) that extends the frequency range of the SG384 and SG386 to 8.10 GHz. Low-jitter differential clock outputs (Opt. 01) are available, and an external I/Q modulation input (Opt. 03) is also offered. For demanding applications, the SG380 Series can be ordered with a rubidium timebase (Opt. 04).
On the Front Panel
The SG380 Series Signal Generators have two front-panel outputs with overlapping frequency ranges. A BNC provides outputs from DC to 62.5 MHz with adjustable offsets and amplitudes from 1 mV to 1 Vrms into a 50 Ω load. An N-type output sources frequencies from 950 kHz to 4.05 GHz with power from +16.5 dBm to -110 dBm (amplitude from 1 Vrms to 0.707 µVrms) into a 50 Ω load.
Modulation
The SG380 Signal Generators offer a wide variety of modulation capabilities. Modes include amplitude modulation (AM), frequency modulation (FM), phase modulation (ΦM), and pulse modulation. There is an internal modulation source as well as an external modulation input. The internal modulation source produces sine, ramp, saw, square, and noise waveforms. An external modulation signal may be applied to the rear-panel modulation input. The internal modulation generator is available as an output on the rear panel.
Unlike traditional analog signal generators, the SG380 Series can sweep continuously from DC to 62.5 MHz. And for frequencies above 62.5 MHz, each sweep range covers more than an octave.
OCXO or Rubidium Timebase
The SG380 Series come with a oven-controlled crystal oscillator (OCXO) timebase. The timebase uses a third-overtone stress-compensated 10 MHz resonator in a thermostatically controlled oven. The timebase provides very low phase noise and very low aging. An optional rubidium oscillator (Opt. 04) may be ordered to substantially reduce frequency aging and improve temperature stability.
The internal 10 MHz timebase (either the standard OCXO or the optional rubidium reference) is available on a rear-panel output. An external 10 MHz timebase reference may be supplied to the rear-panel timebase input.
Square Wave Clock Outputs
Optional differential clock outputs (Opt. 01) are available on the rear-panel that make the SG380 Series precision clock generators in addition to signal generators. Transition times are typically 35 ps, and both the offset and amplitudes of the clock outputs can be adjusted for compliance with PECL, ECL, RSECL, LVDS, CML, and NIM levels.
I/Q Inputs
Optional I/Q inputs (Opt. 03) allow I & Q baseband signals to modulate carriers from 400 MHz to 6.075 GHz. This option also allows the I/Q modulator to be driven by an internal noise generator with adjustable amplitude and bandwidth. Rear-panel outputs allow the noise source to viewed or used for other purposes.
Output Frequency Doubler
The SG384 and SG386 can be ordered with a frequency doubler (Opt. 02) that extends the frequency range to 8.10 GHz. The amplitude of the rear-panel RF output can be adjusted from –10 dBm to +13 dBm. This option also comes with a bias source output which can be set with 5 mV resolution over ±10 VDC.
Easy Communication
Remote operation is supported with GPIB, RS-232 and Ethernet interfaces. All instrument functions can be controlled and read over any of the interfaces. Up to nine instrument configurations can be saved in non-volatile memory.
A New Frequency Synthesis Technique
The SG380 Series Signal Generators are based on a new frequency synthesis technique called Rational Approximation Frequency Synthesis (RAFS). RAFS uses small integer divisors in a conventional phase-locked loop (PLL) to synthesize a frequency that would be close to the desired frequency (typically within ±100 ppm) using the nominal PLL reference frequency. The PLL reference frequency, which is sourced by a voltage control crystal oscillator that is phase locked to a dithered direct digital synthesizer, is adjusted so that the PLL generates the exact frequency. Doing so provides a high phase comparison frequency (typically 25 MHz) yielding low phase noise while moving the PLL reference spurs far from the carrier where they can be easily removed. The end result is an agile RF source with low phase noise, essentially infinite frequency resolution, without the spurs of fractional-N synthesis or the cost of a YIG oscillator.
Key Features of SRS Stanford Research Systems Model SG382 SG384 SG386 RF Signal Generators
Specification of SG382 SG384 SG386 RF Signal Generators
Frequency Setting | |
Frequency ranges | DC to 62.5MHz (BNC output, all models) |
SG382 | 950 kHz to 2.025GHz (N-type output) |
SG384 | 950 kHz to 4.05GHz (N-type output) 4.05GHz to 8.1GHz (w/ Opt. 02) |
SG386 | 950 kHz to 6.075GHz (N-type output) 6.075GHz to 8.1GHz (w/ Opt. 02) |
Frequency resolution | 1µHz at any frequency |
Switching speed | Frequency error |
Frequency error | <(10–18+timebase error)×fC |
Frequency stability | 1×10–11 (1 s Allan variance) |
Front-Panel BNC Output | |
Frequency range | DC to 62.5MHz |
Amplitude | 1.00Vrms to 0.001Vrms |
Offset | ±1.5VDC |
Offset resolution | 5mV |
Max. excursion | 1.817V(amplitude+offset) |
Amplitude resolution | <1% |
Amplitude accuracy | ±5 % |
Harmonics | <–40 dBc |
Spurious | <–75 dBc |
Output coupling | DC, 50Ω ±2% |
User load | 50Ω |
Reverse protection | ±5VDC |
Front-Panel N-Type Output | |
Frequency range | |
SG382 | 950 kHz to 2.025 GHz |
SG384 | 950 kHz to 4.05 GHz |
SG386 | 950 kHz to 6.075 GHz |
Power output | |
SG382 | +16.5 dBm to -110 dBm |
SG384 | +16.5 dBm to -110 dBm (<3 GHz) |
SG386 | +16.5 dBm to -110 dBm (<4 GHz) |
Voltage output | |
SG382 | 1.5 Vrms to 0.7 µVrms |
SG384 | 1.5 Vrms to 0.7 µVrms (<3 GHz) |
SG386 | 1.5 Vrms to 0.7 µVrms (<4 GHz) |
Power resolution | 0.01 dBm |
Power accuracy | ±1 dB (±2 dB above 4 GHz and above +5 dBm or below -100 dBm) |
Output coupling | AC, 50 Ω |
User load | 50 Ω |
VSWR | <1.6 |
Reverse protection | 30 VDC, +25 dBm RF |
Spectral Purity of RF Out (referenced to 1 GHz*) | |
Sub harmonics | None (no doubler used below 4 GHz) |
Harmonics | <-25 dBc (<+7 dBm on N-type output) |
Spurious | |
<10 kHz offset | <-65 dBc |
>10 kHz offset | <-75 dBc |
Phase noise (typ.) | |
10 Hz offset | -80 dBc/Hz |
1 kHz offset | -102 dBc/Hz |
20 kHz offset | -116 dBc/Hz (SG382 & SG384), |
-114 dBc/Hz (SG386) | |
1 MHz offset | -130 dBc/Hz (SG382 & SG384), |
-124 dBc/Hz (SG386) | |
Residual FM (typ.) | 1 Hz rms (300 Hz to 3 kHz bandwidth) |
Residual AM (typ.) | 0.006 % rms (300 Hz to 3 kHz bandwidth) |
Phase Setting on Front-Panel Outputs | |
Max. phase step | ±360° |
Phase resolution | 0.01° (DC to 100 MHz) |
0.1° (100 MHz to 1 GHz) | |
1.0° (1 GHz to 6.075 GHz) | |
Standard OCXO Timebase | |
Oscillator type | Oven controlled, 3rd OT, SC-cut crystal |
Stability (0 to 45° C) | <±0.002 ppm |
Aging | <±0.05 ppm/year |
Rubidium Timebase (opt. 04) | |
Oscillator type | Oven controlled, 3rd OT, SC-cut crystal |
Physics package | Rubidium vapor frequency discriminator |
Stability (0 to 45° C) | <±0.0001 ppm |
Aging | <±0.001 ppm/year |
Timebase Input | |
Frequency | 10 MHz, ±2 ppm |
Amplitude | 0.5 to 4 Vpp (-2 dBm to +16 dBm) |
Input impedance | 50 Ω, AC coupled |
Ordering Information for SG382 SG384 SG386
SG382 2GHz signal generator
SG384 4GHz signal generator
SG386 6GHz signal generator
Option 01 Rear-panel clock outputs
Option 02 8GHz doubler & DC bias
(SG384 and SG386 only)
Option 03 External I/Q modulation
Option 04 Rubidium timebase
RM2U-S Single rack mount kit
RM2U-D Dual rack mount kit
1.Can you ship order to Canada or Australia?
Yes,we can .We send orders worldwide.
2. What delivery method do you use? and delivery time?
We can ship by EMS,DHL,FedEx,UPS,TNT with tracking number. Usual delivery time is 4-7 workdays.
3. What is your payment term?
100% T/T payment before shipment.
4. How can I ask any other question?
You can contact us online or leave us messages below.
Brand Name: | SRS |
Model Number: | SG382 SG384 SG386 |
MOQ: | 1 set |
Price: | Negotiation |
Payment Terms: | T/T |
SRS Stanford Research Systems Model SG380 Series RF Signal Generators SG382 SG384 SG386
Description of SRS Stanford Research Systems Model SG382 SG384 SG386 RF Signal Generators
Introducing the new SG380 Series RF Signal Generators—finally, high performance, affordable RF sources.
The SG380 Series RF Signal Generators use a unique, innovative architecture (Rational Approximation Frequency Synthesis) to deliver ultra-high frequency resolution (1 µHz), excellent phase noise, and versatile modulation capabilities (AM, FM, ØM, pulse modulation and sweeps) at a fraction of the cost of competing designs.
The SG380 Series RF Signal Generators use a unique, innovative architecture (Rational Approximation Frequency Synthesis) to deliver ultra-high frequency resolution (1 µHz), excellent phase noise, and versatile modulation capabilities (AM, FM, ØM, pulse modulation and sweeps) at a fraction of the cost of competing designs. The standard models produce sine waves from DC to 2.025 GHz (SG382), 4.05 GHz (SG384) and 6.075 GHz (SG386).
The standard models produce sine waves from DC to 2.025 GHz (SG382), 4.05 GHz (SG384) and 6.075 GHz (SG386). There is an optional frequency doubler (Opt. 02) that extends the frequency range of the SG384 and SG386 to 8.10 GHz. Low-jitter differential clock outputs (Opt. 01) are available, and an external I/Q modulation input (Opt. 03) is also offered. For demanding applications, the SG380 Series can be ordered with a rubidium timebase (Opt. 04).
On the Front Panel
The SG380 Series Signal Generators have two front-panel outputs with overlapping frequency ranges. A BNC provides outputs from DC to 62.5 MHz with adjustable offsets and amplitudes from 1 mV to 1 Vrms into a 50 Ω load. An N-type output sources frequencies from 950 kHz to 4.05 GHz with power from +16.5 dBm to -110 dBm (amplitude from 1 Vrms to 0.707 µVrms) into a 50 Ω load.
Modulation
The SG380 Signal Generators offer a wide variety of modulation capabilities. Modes include amplitude modulation (AM), frequency modulation (FM), phase modulation (ΦM), and pulse modulation. There is an internal modulation source as well as an external modulation input. The internal modulation source produces sine, ramp, saw, square, and noise waveforms. An external modulation signal may be applied to the rear-panel modulation input. The internal modulation generator is available as an output on the rear panel.
Unlike traditional analog signal generators, the SG380 Series can sweep continuously from DC to 62.5 MHz. And for frequencies above 62.5 MHz, each sweep range covers more than an octave.
OCXO or Rubidium Timebase
The SG380 Series come with a oven-controlled crystal oscillator (OCXO) timebase. The timebase uses a third-overtone stress-compensated 10 MHz resonator in a thermostatically controlled oven. The timebase provides very low phase noise and very low aging. An optional rubidium oscillator (Opt. 04) may be ordered to substantially reduce frequency aging and improve temperature stability.
The internal 10 MHz timebase (either the standard OCXO or the optional rubidium reference) is available on a rear-panel output. An external 10 MHz timebase reference may be supplied to the rear-panel timebase input.
Square Wave Clock Outputs
Optional differential clock outputs (Opt. 01) are available on the rear-panel that make the SG380 Series precision clock generators in addition to signal generators. Transition times are typically 35 ps, and both the offset and amplitudes of the clock outputs can be adjusted for compliance with PECL, ECL, RSECL, LVDS, CML, and NIM levels.
I/Q Inputs
Optional I/Q inputs (Opt. 03) allow I & Q baseband signals to modulate carriers from 400 MHz to 6.075 GHz. This option also allows the I/Q modulator to be driven by an internal noise generator with adjustable amplitude and bandwidth. Rear-panel outputs allow the noise source to viewed or used for other purposes.
Output Frequency Doubler
The SG384 and SG386 can be ordered with a frequency doubler (Opt. 02) that extends the frequency range to 8.10 GHz. The amplitude of the rear-panel RF output can be adjusted from –10 dBm to +13 dBm. This option also comes with a bias source output which can be set with 5 mV resolution over ±10 VDC.
Easy Communication
Remote operation is supported with GPIB, RS-232 and Ethernet interfaces. All instrument functions can be controlled and read over any of the interfaces. Up to nine instrument configurations can be saved in non-volatile memory.
A New Frequency Synthesis Technique
The SG380 Series Signal Generators are based on a new frequency synthesis technique called Rational Approximation Frequency Synthesis (RAFS). RAFS uses small integer divisors in a conventional phase-locked loop (PLL) to synthesize a frequency that would be close to the desired frequency (typically within ±100 ppm) using the nominal PLL reference frequency. The PLL reference frequency, which is sourced by a voltage control crystal oscillator that is phase locked to a dithered direct digital synthesizer, is adjusted so that the PLL generates the exact frequency. Doing so provides a high phase comparison frequency (typically 25 MHz) yielding low phase noise while moving the PLL reference spurs far from the carrier where they can be easily removed. The end result is an agile RF source with low phase noise, essentially infinite frequency resolution, without the spurs of fractional-N synthesis or the cost of a YIG oscillator.
Key Features of SRS Stanford Research Systems Model SG382 SG384 SG386 RF Signal Generators
Specification of SG382 SG384 SG386 RF Signal Generators
Frequency Setting | |
Frequency ranges | DC to 62.5MHz (BNC output, all models) |
SG382 | 950 kHz to 2.025GHz (N-type output) |
SG384 | 950 kHz to 4.05GHz (N-type output) 4.05GHz to 8.1GHz (w/ Opt. 02) |
SG386 | 950 kHz to 6.075GHz (N-type output) 6.075GHz to 8.1GHz (w/ Opt. 02) |
Frequency resolution | 1µHz at any frequency |
Switching speed | Frequency error |
Frequency error | <(10–18+timebase error)×fC |
Frequency stability | 1×10–11 (1 s Allan variance) |
Front-Panel BNC Output | |
Frequency range | DC to 62.5MHz |
Amplitude | 1.00Vrms to 0.001Vrms |
Offset | ±1.5VDC |
Offset resolution | 5mV |
Max. excursion | 1.817V(amplitude+offset) |
Amplitude resolution | <1% |
Amplitude accuracy | ±5 % |
Harmonics | <–40 dBc |
Spurious | <–75 dBc |
Output coupling | DC, 50Ω ±2% |
User load | 50Ω |
Reverse protection | ±5VDC |
Front-Panel N-Type Output | |
Frequency range | |
SG382 | 950 kHz to 2.025 GHz |
SG384 | 950 kHz to 4.05 GHz |
SG386 | 950 kHz to 6.075 GHz |
Power output | |
SG382 | +16.5 dBm to -110 dBm |
SG384 | +16.5 dBm to -110 dBm (<3 GHz) |
SG386 | +16.5 dBm to -110 dBm (<4 GHz) |
Voltage output | |
SG382 | 1.5 Vrms to 0.7 µVrms |
SG384 | 1.5 Vrms to 0.7 µVrms (<3 GHz) |
SG386 | 1.5 Vrms to 0.7 µVrms (<4 GHz) |
Power resolution | 0.01 dBm |
Power accuracy | ±1 dB (±2 dB above 4 GHz and above +5 dBm or below -100 dBm) |
Output coupling | AC, 50 Ω |
User load | 50 Ω |
VSWR | <1.6 |
Reverse protection | 30 VDC, +25 dBm RF |
Spectral Purity of RF Out (referenced to 1 GHz*) | |
Sub harmonics | None (no doubler used below 4 GHz) |
Harmonics | <-25 dBc (<+7 dBm on N-type output) |
Spurious | |
<10 kHz offset | <-65 dBc |
>10 kHz offset | <-75 dBc |
Phase noise (typ.) | |
10 Hz offset | -80 dBc/Hz |
1 kHz offset | -102 dBc/Hz |
20 kHz offset | -116 dBc/Hz (SG382 & SG384), |
-114 dBc/Hz (SG386) | |
1 MHz offset | -130 dBc/Hz (SG382 & SG384), |
-124 dBc/Hz (SG386) | |
Residual FM (typ.) | 1 Hz rms (300 Hz to 3 kHz bandwidth) |
Residual AM (typ.) | 0.006 % rms (300 Hz to 3 kHz bandwidth) |
Phase Setting on Front-Panel Outputs | |
Max. phase step | ±360° |
Phase resolution | 0.01° (DC to 100 MHz) |
0.1° (100 MHz to 1 GHz) | |
1.0° (1 GHz to 6.075 GHz) | |
Standard OCXO Timebase | |
Oscillator type | Oven controlled, 3rd OT, SC-cut crystal |
Stability (0 to 45° C) | <±0.002 ppm |
Aging | <±0.05 ppm/year |
Rubidium Timebase (opt. 04) | |
Oscillator type | Oven controlled, 3rd OT, SC-cut crystal |
Physics package | Rubidium vapor frequency discriminator |
Stability (0 to 45° C) | <±0.0001 ppm |
Aging | <±0.001 ppm/year |
Timebase Input | |
Frequency | 10 MHz, ±2 ppm |
Amplitude | 0.5 to 4 Vpp (-2 dBm to +16 dBm) |
Input impedance | 50 Ω, AC coupled |
Ordering Information for SG382 SG384 SG386
SG382 2GHz signal generator
SG384 4GHz signal generator
SG386 6GHz signal generator
Option 01 Rear-panel clock outputs
Option 02 8GHz doubler & DC bias
(SG384 and SG386 only)
Option 03 External I/Q modulation
Option 04 Rubidium timebase
RM2U-S Single rack mount kit
RM2U-D Dual rack mount kit
1.Can you ship order to Canada or Australia?
Yes,we can .We send orders worldwide.
2. What delivery method do you use? and delivery time?
We can ship by EMS,DHL,FedEx,UPS,TNT with tracking number. Usual delivery time is 4-7 workdays.
3. What is your payment term?
100% T/T payment before shipment.
4. How can I ask any other question?
You can contact us online or leave us messages below.