EC2500ETTTS-33.0000M datasheet, PDF

Datasheet> All Categories > Passive components> oscillator> EC2500ETTTS-33.0000M

EC2500ETTTS-33.0000M: DescriptionCRYSTAL OSCILLATOR, CLOCK, 33 MHz, CMOS/LSTTL OUTPUT, ROHS COMPLIANT, CERAMIC, SMD, 4 PIN; CategoryPassive components oscillator; File Size126KB，2 Pages; ManufacturerECLIPTEK; Websitehttp://www.ecliptek.com; Environmental Compliance

Download Datasheet Parametric View All

EC2500ETTTS-33.0000M Overview

CRYSTAL OSCILLATOR, CLOCK, 33 MHz, CMOS/LSTTL OUTPUT, ROHS COMPLIANT, CERAMIC, SMD, 4 PIN

EC2500ETTTS-33.0000M Parametric

Parameter Name	Attribute value
Is it lead-free?	Lead free
Is it Rohs certified?	conform to
Maker	ECLIPTEK
Reach Compliance Code	compli
Other features	TRI-STATE; ENABLE/DISABLE FUNCTION; BULK
maximum descent time	10 ns
Frequency Adjustment - Mechanical	NO
frequency stability	100%
JESD-609 code	e4
Manufacturer's serial number	EC25
Installation features	SURFACE MOUNT
Nominal operating frequency	33 MHz
Maximum operating temperature	85 °C
Minimum operating temperature	-40 °C
Oscillator type	CMOS/LSTTL
Output load	10 LS TTL, 30 pF
physical size	7.0mm x 5.0mm x 1.6mm
longest rise time	10 ns
Maximum supply voltage	5.5 V
Minimum supply voltage	4.5 V
Nominal supply voltage	5 V
surface mount	YES
maximum symmetry	55/45 %
Terminal surface	Nickel/Gold (Ni/Au)

Preview

Download Datasheet

View All

EC25

Series

• Crystal Clock Oscillators

• CMOS/TTL Output

• +5.0V Supply Voltage

• Tri-State Output Function

• High and Low Output Drive Options

• 4 Pad Ceramic SMD Package

• RoHS Compliant (Pb-Free)

ELECTRICAL SPECIFICATIONS

Frequency Range

Operating Temperature Range

Storage Temperature Range

Supply Voltage (V

)

Input Current (No Load)

EC25

H 1.6

L 7.0

W 5.0

OSCILLATOR

Frequency Tolerance / Stability

Output Voltage Logic High (V

)

Output Current (I

)

Output Voltage Logic Low (V

)

Output Current (I

)

Rise / Fall Time

1.544MHz to 32.000MHz

32.001MHz to 50.000MHz

50.001MHz to 70.000MHz

70.001MHz to 106.250MHz

Inclusive of all conditions: Calibration Tolerance at 25°C,

Frequency Stability over the Operating Temperature Range,

Supply Voltage Change, Output Load Change, First Year

Aging at 25°C, Shock, and Vibration

w/TTL Load

w/CMOS Load

Load Drive Option "Blank"

Load Drive Option "Y"

w/TTL Load

w/CMOS Load

Load Drive Option "Blank"

Load Drive Option "Y"

1.544MHz to 106.250MHz

-10°C to +70°C or

-40°C to +85°C

-55°C to +125°C

5.0V

±10%

10mA Maximum

30mA Maximum

50mA Maximum

60mA Maximum

±100ppm, ±50ppm, ±25ppm or

±20ppm Maximum

2.4V

Minimum

-0.5V

Minimum

-4mA <35.000MHz, -16mA >35.000MHz

-16mA <70.000MHz

0.4V

Maximum

0.5V

Maximum

+4mA <35.000MHz, +16mA >35.000MHz

+16mA <70.000MHz

10nSec Max. <70.000MHz

5nSec Max. >70.000MHz

5nSec Max. <70.000MHz

50 ±10(%) (Standard)

50 ±5(%) (Optional)

50 ±5(%) (Optional) -10°C to +70°C Only

10LSTTL Load or 30pF CMOS Load

10LSTTL Load or 15pF CMOS Load

10TTL Load or 50pF CMOS Load

Enables Output

Disables Output: High Impedance

10mSeconds Maximum

1pSeconds Maximum

10% to 90% of Waveform w/30pF CMOS Load; 0.4V

to 2.4V

w/10LSTTL Load

10% to 90% of Waveform w/15pF CMOS Load; 0.4V

to 2.4V

w/10LSTTL Load

10% to 90% of Waveform w/50pF CMOS Load; 0.4V

to 2.4V

w/10TTL Load

Duty Cycle

at 50% of Waveform w/CMOS Load or 1.4V

w/TTL Load <70.000MHz

at 50% of Waveform w/TTL Load or w/CMOS Load >70.000MHz

at 50% of Waveform w/TTL Load or w/CMOS Load <80.000MHz

at 50% of Waveform w/CMOS Load (80.001MHz to 100.000MHz)

Load Drive Capability

<70.000MHz

>70.000MHz

<70.000MHz (Option “Y”)

No Connection

Tri-State Input Voltage

≥2.0V

≤0.8V

Start Up Time

RMS Phase Jitter

12KHz to 20MHz offset frequency

MANUFACTURER

Recommended Resources

Two-channel subwoofer circuit

Simple IQ game circuit - main circuit diagram

CMOS interface circuit for driving large current coils

Negative feedback voltmeter

Comb pulse signal oscillator

555 car wiper automatic controller circuit

Help: Software Outsourcing Company: Does anyone know of any small or medium-sized companies that develop mobile software? Can you provide some information, or how can I find information about these companies? Thank you....; hkr10221 Embedded System

Precision Differential Output Instrumentation Amplifier Explained: State-of-the-art analog-to-digital converters (ADCs) are capable of accepting differential input signals, allowing the entire signal path from the sensor to be presented to the ADC as a differential s...; rain Analog electronics

I also show you the new bit I just received: I just received a new bit and I'll show you what's inside. I'll study it slowly later....; z755924843 MicroPython Open Source section

G2553 simulates serial port driver 12864. I need advice from experts on how to write and read the data in 12864.: This is the 12864 header file part. Note that I am using the simulated serial port, not serial communication. #include void int_port(void) //Pin initialization{ P1SEL=~BIT4; //P1.4 simulates SID, set ...; tanfeng193 Microcontroller MCU

Understand these two stories and learn to cherish.: [size=4]At a friend's wedding, the MC took out a 100-dollar bill and asked everyone present, "If anyone wants one, please raise your hand." Everyone thought that the MC was trying to trick people, so ...; daijun Talking

Problem getting ARP cache example: I am reading Chapter 12 of "Linux Network Programming", Section 12.6, Part 5. 12.6.5, Use ioctl() function to operate ARP cache. There is an example of obtaining the hardware address corresponding to ...; chenbingjy Linux and Android

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