3GPW8-F-150N-FREQ datasheet, PDF

Datasheet> All Categories > Passive components> oscillator> 3GPW8-F-150N-FREQ

3GPW8-F-150N-FREQ: DescriptionLVPECL Output Clock Oscillator, 0.75MHz Min, 800MHz Max, DIP-8/4; CategoryPassive components oscillator; File Size109KB，1 Pages; ManufacturerEuroquartz; Websitehttp://www.euroquartz.co.uk/

Download Datasheet Parametric View All

3GPW8-F-150N-FREQ Overview

LVPECL Output Clock Oscillator, 0.75MHz Min, 800MHz Max, DIP-8/4

3GPW8-F-150N-FREQ Parametric

Parameter Name	Attribute value
Is it lead-free?	Contains lead
Is it Rohs certified?	incompatible
Reach Compliance Code	compliant
Maximum control voltage	2 V
Minimum control voltage	1.3 V
maximum descent time	0.7 ns
Frequency Adjustment - Mechanical	NO
Frequency offset/pull rate	150 ppm
frequency stability	100%
Installation features	THROUGH HOLE MOUNT
Maximum operating frequency	800 MHz
Minimum operating frequency	0.75 MHz
Maximum operating temperature	85 °C
Minimum operating temperature	-40 °C
Oscillator type	LVPECL
Output load	50 OHM
physical size	12.8mm x 12.8mm x 5.08mm
longest rise time	0.7 ns
Maximum supply voltage	3.465 V
Minimum supply voltage	3.135 V
Nominal supply voltage	3.3 V
surface mount	NO
maximum symmetry	55/45 %
Base Number Matches	1

Preview

Download Datasheet

View All

EURO

QUARTZ

8 pin Dual-in-Line

Frequency range 750kHz to 800MHz

LVPECL Output

Supply Voltage 3.3 VDC

Phase jitter 2.35ps typical

Pull range from ±30ppm to ±150ppm

DESCRIPTION

GPW8 VCXOs are packaged in an industry-standard 8 pin dual-in-

line package. Typical phase jitter for GPW series VCXOs is 2.35ps.

Output is LVPECL. Applications include phase lock loop, SONET/ATM,

set-top boxes, MPEG , audio/video modulation, video game consoles

and HDTV.

SPECIFICATION

Frequency Range:

Supply Voltage:

Output Logic:

RMS Period Jitter:

Peak to Peak Jitter:

Phase Jitter:

Initial Frequency Accuracy:

Output Voltage HIGH (1):

Output Voltage LOW (0):

OUTLINE & DIMENSIONS

GPW8 PECL VCXO

750.0kHz to 800.0MHz

Pulling Range:

Control Voltage Range:

Temperature Stability:

Output Load:

Rise/Fall Times:

Duty Cycle:

Start-up Time:

Current Consumption:

Static Discharge Protection:

Storage Temperature:

Ageing:

Enable/Disable:

RoHS Status:

750.0kHz to 800.0MHz

3.3 VDC ±5%

LVPECL

4.3ps typical

27.0ps typical

2.35ps typical

Tune to the nominal frequency

with Vc= 1.65 ±0.2VDC

Vdd-1.025V minimum

Vdd-0.880V maximum

Vdd-1.810V minimum

Vdd-1.620V maximum

(RL=50 to Vdd-2V)

From ±30ppm to ±150ppm

1.65 ±0.35 Volts

See table

50W into Vdd or Thevenin equiv.

0.5ns typ., 0.7ns max.

20% Vdd to 80% Vdd

50% ±5%

(Measured at Vdd-1.3V)

10ms maximum, 5ms typical

75mA maximum at 212.5MHz

80mA maximum at 622.08MHz

2kV maximum

-55° to +150°C

±2ppm per year maximum

Not implemented, 4 pin package

Fully compliant or non-compliant

versions available

PART NUMBERING

Example:

3GPW8G-B-80N-60.000

FREQUENCY STABILITY

Stability Code Stability ±ppm Temp. Range

0°~+70°C

100

0°~+70°C

-40°~+85°C

100

-40°~+85°C

If non-standard frequency stability is required

Use ‘I’ followed by stability, i.e. I20 for ±20ppm

Supply Voltage

3 = +3.3V

Series Designator

GPW8

RoHS Status

G = RoHs compliant

Blank = RoHS non-compliant

Stability over temperature range

(See table)

Pullability in ±ppm

Pullability determinator

N = minimum

M = maximum

T = Typical

Frequency in MHz

EUROQUARTZ LIMITED Blacknell Lane CREWKERNE Somerset UK TA18 7HE

Tel: +44 (0)1460 230000 Fax: +44 (0)1460 230001 info@euroquartz.co.uk www.euroquartz.co.uk

Recommended Resources

Production of power carrier communication switch circuit based on 51 microcontroller

Video codec circuit

Standard application circuit diagram of MAX742

Home backup power

Oscillators used in electronic musical instruments

Computer motherboard circuit diagram 440GX_20

How to use AF_DataRequest() to send information?: Does the CC2530 network need to be bound before communication can proceed? If the terminal node and the coordinator are not bound, can the AF_DataRequest function be used to send information directly ...; freebird_sp RF/Wirelessly

Analysis of the static working point of transistor: I know that RB is a negative feedback circuit, but how are the parameters of this circuit calculated? Can someone please give me some advice?...; 零下12度半 Analog electronics

Can anyone send me a copy of the HIPS active defense system source code?: Is there any source code for this kind of system? It is best to write it in vc. lockdog_jia@yahoo.com.cn...; shangwlscp Embedded System

Ask for help in understanding the program in the password protection module: Ask for help in understanding the program in the password protection moduleIn the TI routine, the CSM module has such a program, as follows: Uint16 CsmUnlock() {volatile Uint16 temp;EALLOW;CsmRegs.KEY...; 安_然 DSP and ARM Processors

The relationship between time domain and frequency domain, a picture tells you ~: ...; qinkaiabc Analogue and Mixed Signal

Share with you: Access control circuit diagram: When the company just moved, the access control was broken. Later I forgot how to fix it, but I found a few circuit diagrams at that time. This may be of some value. I would like to share it with you....; gina Industrial Control Electronics

Shortcut: E0 E1 E2 E3 E4 E5 E6 E7 E8 E9 EA EB EC ED EE EF EG EH EI EJ EK EL EM EN EO EP EQ ER ES ET EU EV EW EX EY EZ F0 F1 F2 F3 F4 F5 F6 F7 F8 F9 FA FB FC FD FE FF FG FH FI FJ FK FL FM FN FO FP FQ FR FS FT FU FV FW FX FY FZ G0 G1 G2 G3 G4 G5 G6 G7 G8 G9 GA GB GC GD GE GF GG GH GI GJ GK GL GM GN GO GP GQ GR GS GT GU GV GW GX GZ H0 H1 H2 H3 H4 H5 H6 H7 H8 HA HB HC HD HE HF HG HH HI HJ HK HL HM HN HO HP HQ HR HS HT HU HV HW HX HY HZ I1 I2 I3 I4 I5 I6 I7 IA IB IC ID IE IF IG IH II IK IL IM IN IO IP IQ IR IS IT IU IV IW IX J0 J1 J2 J6 J7 JA JB JC JD JE JF JG JH JJ JK JL JM JN JP JQ JR JS JT JV JW JX JZ K0 K1 K2 K3 K4 K5 K6 K7 K8 K9 KA KB KC KD KE KF KG KH KI KJ KK KL KM KN KO KP KQ KR KS KT KU KV KW KX KY KZ

Popular Components