EH1345HSTS-75.000M datasheet, PDF

Datasheet> All Categories > Passive components> oscillator> EH1345HSTS-75.000M

EH1345HSTS-75.000M: DescriptionCRYSTAL OSCILLATOR, CLOCK, 75 MHz, LVCMOS OUTPUT, ROHS COMPLIANT, METAL, DIP-8/4; CategoryPassive components oscillator; File Size168KB，6 Pages; ManufacturerECLIPTEK; Websitehttp://www.ecliptek.com; Environmental Compliance

Download Datasheet Parametric View All

EH1345HSTS-75.000M Overview

CRYSTAL OSCILLATOR, CLOCK, 75 MHz, LVCMOS OUTPUT, ROHS COMPLIANT, METAL, DIP-8/4

EH1345HSTS-75.000M Parametric

Parameter Name	Attribute value
Is it Rohs certified?	conform to
Maker	ECLIPTEK
Reach Compliance Code	compliant
Is Samacsys	N
Other features	TRI-STATE; ENABLE/DISABLE FUNCTION
maximum descent time	4 ns
Frequency Adjustment - Mechanical	NO
frequency stability	50%
JESD-609 code	e3
Manufacturer's serial number	EH13
Installation features	THROUGH HOLE MOUNT
Nominal operating frequency	75 MHz
Maximum operating temperature	70 °C
Minimum operating temperature
Oscillator type	LVCMOS
Output load	15 pF
physical size	13.2mm x 13.2mm x 5.6mm
longest rise time	4 ns
Maximum supply voltage	3.6 V
Minimum supply voltage	3 V
Nominal supply voltage	3.3 V
surface mount	NO
maximum symmetry	60/40 %
Terminal surface	Matte Tin (Sn) - with Nickel (Ni) barrier
Base Number Matches	1

Preview

Download Datasheet

View All

EH1345HSTS-75.000M

EH13 45 HS

Series

RoHS Compliant (Pb-free) 3.3V 8 Pin DIP Metal

Thru-Hole LVCMOS High Frequency Oscillator

Frequency Tolerance/Stability

±50ppm Maximum

Package

Operating Temperature Range

0°C to +70°C

RoHS

Nominal Frequency

75.000MHz

TS -75.000M

Pin 1 Connection

Tri-State (Disabled Output: High Impedance)

Duty Cycle

50 ±10(%)

ELECTRICAL SPECIFICATIONS

Nominal Frequency

Frequency Tolerance/Stability

75.000MHz

±50ppm Maximum (Inclusive of all conditions: Calibration Tolerance at 25°C, Frequency Stability over the

Operating Temperature Range, Supply Voltage Change, Ouput Load Change, 1st Year Aging at 25°C,

Shock, and Vibration.)

±5ppm/year Maximum

0°C to +70°C

3.3Vdc ±0.3Vdc

35mA Maximum (No Load)

2.7Vdc Minimum (IOH = -8mA)

0.5Vdc Maximum (IOL = +8mA)

4nSec Maximum (Measured at 20% to 80% of waveform)

50 ±10(%) (Measured at 50% of waveform)

15pF Maximum

CMOS

Tri-State (Disabled Output: High Impedance)

70% of Vdd Minimum to enable output, 20% of Vdd Maximum to disable output (High Impedance), No

Connect to enable output.

±250pSec Maximum, ±100pSec Typical

±50pSec Maximum, ±40pSec Typical

10mSec Maximum

-55°C to +125°C

Aging at 25°C

Operating Temperature Range

Supply Voltage

Input Current

Output Voltage Logic High (Voh)

Output Voltage Logic Low (Vol)

Rise/Fall Time

Duty Cycle

Load Drive Capability

Output Logic Type

Pin 1 Connection

Tri-State Input Voltage (Vih and Vil)

Absolute Clock Jitter

One Sigma Clock Period Jitter

Start Up Time

Storage Temperature Range

ENVIRONMENTAL & MECHANICAL SPECIFICATIONS

Fine Leak Test

Gross Leak Test

Lead Integrity

Mechanical Shock

Resistance to Soldering Heat

Resistance to Solvents

Solderability

Temperature Cycling

Vibration

MIL-STD-883, Method 1014, Condition A

MIL-STD-883, Method 1014, Condition C

MIL-STD-883, Method 2004

MIL-STD-202, Method 213, Condition C

MIL-STD-202, Method 210

MIL-STD-202, Method 215

MIL-STD-883, Method 2003

MIL-STD-883, Method 1010

MIL-STD-883, Method 2007, Condition A

www.ecliptek.com | Specification Subject to Change Without Notice | Rev C 3/12/2011 | Page 1 of 6

Recommended Resources

Electronic stable speed motor application circuit

FGDF-3 three-phase low-temperature iron-plated power supply main circuit

Intermittent automatic irrigation controller circuit

acupoint detector

Multifunctional electronic telephone test device circuit diagram

Application of microwave sensing module RD627A

LUA programming environment -- picolua: picolua is a Lua programming environment for Pico. In addition to the Lua runtime, it includes a basic Unix-like shell, a full-screen editor, and basic file management tools. picolua is designed to be...; dcexpert MicroPython Open Source section

Writing ZigBee Module in IAR: I am a novice. I am currently in charge of a ZigBee wireless communication module for a project, the AW5161P2EF. I downloaded the manual, which contains the networking protocol and command configurati...; linee RF/Wirelessly

Is there any software that can quickly derive the equivalent impedance formula for a multi-stage LC series-parallel circuit?: Hello everyone, I've recently been studying the derivation process of various inductance and capacitance values of NFC antenna matching circuits. Referring to the official application documents of NXP...; bobde163 RF/Wirelessly

"Random Talk" about Domestic RISC-V MCU: I have three RISC-V RV32 microcontrollers (GD32VF103 Zhaoyi Innovation, CH32V103 Jiangsu Qinheng, CH2601 Ali Pingtou Ge). RISC-V (pronounced "risk-five") is an open source instruction set architecture...; bigbat Domestic Chip Exchange

When studying the working principle of RCD circuit, what is the energy accumulated in the parasitic inductance?: Is it the parasitic inductance of the switch?Then I saw a circuit similar to RCD function in the PFC circuit. Is the black circle the RCD circuit? Why is it different from the flyback switching power ...; 西里古1992 Analog electronics

There is a spike after the rectifier bridge, which cannot be clamped by a varistor.: There is a spike after the rectifier bridge, which cannot be clamped by the varistor. It can be clamped when the phase is 90 degrees, but not when it is -90 degrees. Is it because the varistor cannot ...; 东莞台强电子侯国良 Power technology

Shortcut: A0 A1 A2 A3 A4 A5 A6 A7 A8 A9 AA AB AC AD AE AF AG AH AI AJ AK AL AM AN AO AP AQ AR AS AT AU AV AW AX AY AZ B0 B1 B2 B3 B4 B5 B6 B7 B8 B9 BA BB BC BD BE BF BG BH BI BJ BK BL BM BN BO BP BQ BR BS BT BU BV BW BX BY BZ C0 C1 C2 C3 C4 C5 C6 C7 C8 C9 CA CB CC CD CE CF CG CH CI CJ CK CL CM CN CO CP CQ CR CS CT CU CV CW CX CY CZ D0 D1 D2 D3 D4 D5 D6 D7 D8 D9 DA DB DC DD DE DF DG DH DI DJ DK DL DM DN DO DP DQ DR DS DT DU DV DW DX DZ

Popular Components