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LEADLESS CHIP CARRIER

Q-TECH

Description

CORPORATION

CRYSTAL CLOCK OSCILLATORS

1.8 to 15Vdc - 732.4Hz to 150MHz

Q-Tech’s Leadless Chip Carrier crystal oscillators

consist of a source clock square wave generator, logic

output buffers and/or logic divider stages, and a round

A high-precision quartz crystal built in a ceramic true

SMD package.

• Made in the USA

• ECCN: EAR99

• DFARS 252-225-7014 Compliant:

Electronic Component Exemption

• USML Registration # M17677

• Wide frequency range from 732.4Hz to 150MHz

• Available as QPL MIL-PRF-55310/19 (QT66T), /20

(QT62T), and /29 (QT66HCD)

• Choice of packages and pin outs

• Choice of supply voltages

• Choice of output logic options ( CMOS, ACMOS,

HCMOS, LVHCMOS, TTL, ECL, PECL, and

LVPECL)

• A

T-Cut crystal

• True SMD hermetically sealed package

• Tight or custom symmetry available

• Low height available

• External tuning capacitor option

• Fundamental and third overtone designs

• Tristate function option D

• Four-point crystal mounts

• Custom design available tailors to meet customer’s

needs

• Q-Tech does not use pure lead or pure tin in its

products

• RoHS compliant

Features

Ordering Information

Solder Dip Option:

T = Standard

S = Solder Dip (*)

Package:

(See page 3)

Q T 6 2 HC D 9M - 2 0. 00 0 M Hz

Q T 62 HC D 9 M - 20.000MHz

Output Frequency

Screening Option:

Blank = No Screening

M = Per MIL-PRF-55310, Level B

(Sample part number)

Tristate Option:

Blank = No Tristate

D = Tristate

Logic & Supply Voltage:

= CMOS +5.0V to +15.0V(**)

= ACMOS

+5.0V

= HCMOS

+5.0V

= TTL

+5.0V

= LVHCMOS

+3.3V

= LVHCMOS

+2.5V

= LVHCMOS

+1.8V

= Z output

Frequency vs. Temperature Code:

= ± 100ppm at 0ºC to +70ºC

3(***) = ± 5ppm at 0ºC to +50ºC

= ± 50ppm at 0ºC to +70ºC

= ± 25ppm at -20ºC to +70ºC

= ± 50ppm at -55ºC to +105ºC

= ± 50ppm at -55ºC to +125ºC

= ± 100ppm at -55ºC to +125ºC

= ± 50ppm at -40ºC to +85ºC

= ± 100ppm at -40ºC to +85ºC

(*) Hot Solder Dip Sn60/Pb40 per MIL-PRF 55310 is optional for an additional cost

(**) Please specify supply voltage when ordering CMOS

(***) Requires an external capacitor

For frequency stability vs. temperature options not listed herein, please request a

custom part number.

For Non-Standard requirements, contact Q-Tech Corporation at

Sales@Q-Tech.com

Applications

• Designed to meet today’s requirements for all voltage

applications

• Wide military clock applications

• Industrial controls

• Microcontroller driver

Packaging Options

Other Options Available For An Additional Charge

• P. I. N. D. test (MIL-STD 883, Method 2020)

• J-leads attached (See page 3 - QT76 and QT77)

Specifications subject to change without prior notice.

• Standard packaging in anti-static plastic tube

• Optional Tape and Reel

Q-TECH Corporation - 10150 W. Jefferson Boulevard, Culver City 90232 - Tel: 310-836-7900 - Fax: 310-836-2157 - www.q-t ec h.com

QPDS-0139 (Revision -, October 2018)

1 of 7

LEADLESS CHIP CARRIER

Q-TECH

Electrical Characteristics

CORPORATION

CRYSTAL CLOCK OSCILLATORS

1.8 to 15Vdc - 732.4Hz to 150MHz

L (*)

Parameters

Output freq. range (Fo)

Supply voltage (Vdd)

QT62, 70

QT71

QT75

QT66, 76, 77

732.4Hz — 15MHz

100kHz — 15MHz

5V ~ 15Vdc ± 10%

-0.5 to +18Vdc

N/A

732.4Hz — 85MHz

15kHz — 85MHz

-0.5 to +7.0Vdc

5.0Vdc ± 10%

732.4Hz — 85MHz

732.4Hz — 125MHz

100kHz — 125MHz

15kHz — 150MHz

-0.5 to +5.0Vdc

3.3Vdc ± 10%

Maximum Applied Voltage (Vdd max.)

Operating temp. (Topr)

Storage temp. (Tsto)

Freq. stability (∆F/∆T)

See Option codes

-62ºC to + 125ºC

Operating supply current

(Idd) (No Load)

Symmetry

(50% of ouput waveform or 1.4Vdc for

TTL)

Rise and Fall times

(with typical load)

Output Load

F and Vdd dependent

3 mA max. at 5V up to 5MHz

25 mA max. at 15V up to 15MHz

20 mA max. -

25 mA max. -

35 mA max. -

45 mA max. -

732.4Hz ~ < 16MHz

16MHz ~ < 40MHz

40MHz ~ < 60MHz

60MHz ~

85MHz

45/55% max. Fo < 4MHz

40/60% max. Fo ≥ 4MHz

30ns max.

(Measured from 10% to 90%)

15pF // 10kΩ

15ns max. Fo < 15kHz

6ns max. Fo 15kHz ~ 39.999MHz

3ns max. Fo 40MHz ~ 160 MHz

(Measured from 10% to 90% CMOS or from 0.8V to 2.0V TTL)

10TTL Fo < 20MHz

6TTL Fo ≥ 20MHz

45/55% max. Fo < 12MHz

40/60% max. Fo ≥ 12MHz

3 mA max. - 732.4Hz ~ < 500kHz

6 mA max. - 500kHz ~ < 16MHz

10 mA max. - 16MHz ~ < 32MHz

20 mA max. - 32MHz ~ < 60MHz

30 mA max. - 60MHz ~ < 100MHz

40 mA max. - 100MHz ~ < 130MHz

50 mA max. - 130MHz ~ ≤150MHz

15pF // 10kΩ

Start-up time (Tstup)

Output voltage (Voh/Vol)

Output Current (Ioh/Iol)

Enable/Disable

Tristate function Pin 1

± 1mA typ. at 5V

± 6.8mA typ. at 15V

0.9 x Vdd min.; 0.1 x Vdd max.

± 24mA

10ms max.

±8 mA

VIH ≥ 2.2V Oscillation;

VIL ≤ 0.8V High Impedance

2.4V min.; 0.4V max.

-1.6mA / TTL

+40μA / TTL

0.9 x Vdd min.; 0.1 x Vdd max.

± 4mA .

Call for details

Jitter RMS 1σ (at 25ºC)

(*)

Z-

Aging (at 70ºC)

8ps typ. - < 40MHz

5ps typ. - ≥ 40MHz

VIH ≥ 0.7 x Vdd Oscillation;

VIL ≤ 0.3 x Vdd High Impedance

15ps typ. - < 40MHz

8ps typ. - ≥ 40MHz

Available in 2.5Vdc (N) or 1.8Vdc (R)

Output logic can drive up to 200 pF load with typical 6ns rise & fall times (tr,

tf)

ECL, PECL, LVPECL are available. Please contact Q-Tech for details.

Q-TECH Corporation

± 5ppm max. first year / ± 2ppm typ. per year thereafter

10150 W. Jefferson Boulevard, Culver City 90232

Tel: 310-836-7900 - Fax: 310-836-2157

www.q-te c h.c om

QPDS-0139 (Revision -, October 2018)

2 of 7

LEADLESS CHIP CARRIER

Q-TECH

Package Outline and Pin Connections

Dimensions are in inches (mm)

QT62

1 44

1 40

CORPORATION

CRYSTAL CLOCK OSCILLATORS

1.8 to 15Vdc - 732.4Hz to 150MHz

QT66

QT70

QT71

QT75

Q-TECH

P/N

FREQ.

D/C S/N

1 28 26

Q-TECH

P/N

FREQ.

D/C S/N

Q-TECH

P/N

FREQ.

D/C S/N

Q-TECH

P/N

FREQ.

D/C S/N

Q-TECH

P/N

FREQ.

D/C S/N

.085

(2.16)

MAX.

.085

(2.16)

MAX.

.085

MAX.

(2.16)

.085

(2.16)

MAX.

.115

(2.92)

MAX

.025

(.635)

.020

(.508)

.050

(1.27)

.360

(9.14)

SQ.

.020

(.508)

.040

(1.02)

.440

(11.18)

SQ.

.025

(.635)

.040

(1.02)

.300

SQ.

(7.62)

.050

(1.27)

.500

SQ.

(12.70)

+ 010

.550 - .005

(13.97

+.25

)

-.127

.200

(5.08)

.650

.085

(2.16)

(16.51)

SQ.

.085

(2.16)

.480

SQ.

(12.19)

.560

.085

(2.16)

SQ.

.085

(2.16)

.450

(11.43)

SQ.

.350 +010

-.005

SQ.

(14.22)

.050

(1.27)

1 40

.040

(1.02)

1 48

.040

(1.02)

1 28 26

.050

(1.27)

(8.89 +.25 )

-.127

1 44

.050

(1.27)

QT76

1 39 37

QT77

1 39 37

QT62

QT66

QT # Conf

12 34

40 34

10 31

37 31

8 22

26 22

10 31

37 31

Vcc

GND

Case Output

E/D

Equivalent

or MIL-PRF-55310

N/C Configuration

/19 = QT66T

/29 = QT66HCD

N/A

/20 = QT62T

Q-TECH

P/N

FREQ.

D/C S/N

Q-TECH

P/N

FREQ.

D/C S/N

QT70

QT71

QT75

MAX.

N/A

.510 /.530

SQ.

(12.95 / 13.46)

.100 / .135

(2.54 / 3.43)

40X Ø .015 ± .003

(40X Ø .38)

.360

SQ.

(9.14)

.085

MAX.

(2.16)

.085

.560 / .610

SQ.

(14.22 / 15.49)

.100 / .135

(2.54 / 3.43)

40X Ø .014

(40X Ø .36)

TYP.

(2.16)

QT76

QT77

.040

(1.02)

.360

SQ.

(9.14)

.040

(1.02)

.085

(2.16)

.480

SQ.

(12.19)

.085

(2.16)

.480

SQ.

(12.19)

1 39 37

.040

(1.02)

1 39 37

.040

(1.02)

• Package material (Header): 91% AL2O3

(Metalization): Tungsten

• Lead finish: Gold Plated – 50µ ~ 80µ inches

Nickel Underplate – 100µ ~ 250µ inches

• Cover: Kovar, Gold Plated – 60µ ~ 90µ inches

Nickel Underplate – 50µ ~ 100µ inches

With attached Preform – 80% Au, 20% Sn

• Package to lid attachment: Seam weld

• Weight: 2.0g typ., 3.0g max.

Package Information

Please contact factory for pin connections on external capacitor (code 3).

Q-TECH Corporation - 10150 W. Jefferson Boulevard, Culver City 90232 - Tel: 310-836-7900 - Fax: 310-836-2157 - www.q-t ec h.com

QPDS-0139 (Revision -,

October

2018)

3 of 7

LEADLESS CHIP CARRIER

Q-TECH

Output Waveform (Typical)

SYMMETRY =

x 100%

CORPORATION

Tape and Reel

1.75±0.1

0.3±.005

Vdd

0.9xVdd

CRYSTAL CLOCK OSCILLATORS

1.8 to 15Vdc - 732.4Hz to 150MHz

ø1.5

2.0±0.1

4.0±0.1

5.5±0.1

VOH

5º Max

0.5xVdd

0.1xVdd

VOL

GND

ø1.5

Test Circuit

ø13.0±0.5

2.0

2.5

Typical test circuit for TTL logic.

Vdd

Vdc

0.1µF

0.01µF

Vdd OUT

OUT

E/D GND

POWER

SUPPLY

120º

LOAD

6 TTL

10 TTL

CL(*)

12pF

20pF

430Ω

270Ω

10kΩ

6kΩ

Dimensions are in mm. Tape is compliant to EIA-481-A.

QT#

QT62

Output

(*) CL inclides the loading effect of the oscilloscope probe.

(mm)

12.57

12.00

9.50

12.57

(mm)

17.30

12.57

12.00

14.60

12.57

(mm)

2.70

2.54

3.00

3.40

2.54

Reel size

Qty per reel

(Diameter in mm)

(pcs)

178mm

330mm

178mm

330mm

178mm

330mm

178mm

330mm

178mm

330mm

178mm

330mm

280

1,200

280

1,200

250

1,000

280

1,200

280

1,200

100

600

Typical test circuit for CMOS logic

+ mA

Power

supply

Vdc

Vdd

0.1µF

E/D

0.01µF

Out

QT66

QT71

GND

15pF

(*)

10k

Ground

Tristate Function

QT75

QT76

QT77

Frequency vs. Temperature Curve

Frequency Stability (PPM)

The Tristate function on pin 1 has a built-in pull-up resistor typical 50kΩ, so it can

be left floating or tied to Vdd without deteriorating the electrical performance.

(*) CL includes probe and jig capacitance

FREQUENCY STABILITY VS. TEMPERATURE QT66T-64.000MHz

-10

-20

-30

-40

-50

-55

-50

-45

-40

-35

-30

-25

-20

-15

-10

-5

30 35 40

Temperature (°C)

2_5

3_5

4_5

100 105 110 115 120 125

1_5

Q-TECH Corporation - 10150 W. Jefferson Boulevard, Culver City 90232 - Tel: 310-836-7900 - Fax: 310-836-2157 - www.q-t ec h.com

QPDS-0139 (Revision -, October 2018)

4 of 7

ø178±1

ø330±1

ø80±1

24.0±0.3

LEADLESS CHIP CARRIER

Q-TECH

Thermal Characteristics

CORPORATION

CRYSTAL CLOCK OSCILLATORS

1.8 to 15Vdc - 732.4Hz to 150MHz

Heat spreading occurs when heat flows into a material layer of

increased cross-sectional area. It is adequate to assume that spreading

occurs at a 45° angle.

The heat transfer model in a hybrid package is described in figure 1.

The total thermal resistance is calculated by summing the thermal

resistances of each material in the thermal path between the device

and hybrid case.

The total thermal resistance RT (see figure 2) between the heat source

(die) to the hybrid case is the Theta Junction to Case (Theta JC)

in°C/W.

• Theta junction to case (Theta JC) for this product is 30°C/W.

• Theta case to ambient (Theta CA) for this part is 100°C/W.

• Theta Junction to ambient (Theta JA) is 130°C/W.

Maximum power dissipation PD for this package at 25°C is:

• PD(max) = (TJ (max) – TA)/Theta JA

• With TJ = 175°C (Maximum junction temperature of die)

• PD(max) = (175 – 25)/130 = 1.15W

RT = R1 + R2 + R3 + R4 + R5

(Figure 1)

(Figure 2)

Environmental Specifications

Q-Tech Standard Screening/QCI (MIL-PRF55310) is available for all of our Leadless Chip Carrier packages. Q-Tech can also

customize screening and test procedures to meet your specific requirements. The Leadless Chip Carrier packages are designed and

processed to exceed the following test conditions:

Environmental Test

Temperature cycling

Constant acceleration

Seal: Fine and Gross Leak

Burn-in

Aging

Vibration sinusoidal

Shock, non operating

Thermal shock, non operating

Ambient pressure, non operating

Resistance to solder heat

Moisture resistance

Terminal strength

Resistance to solvents

Solderability

ESD Classification

Moisture Sensitivity Level

Test Conditions

MIL-STD-883, Method 1010, Cond. B

MIL-STD-883, Method 2001, Cond. A, Y1

MIL-STD-883, Method 1014, Cond. A and C

160 hours, 125°C with load

30 days, 70°C, ± 1.5ppm max

MIL-STD-202, Method 204, Cond. D

MIL-STD-202, Method 213, Cond. I

MIL-STD-202, Method 107, Cond. B

MIL-STD-202, 105, Cond. C, 5 minutes dwell time minimum

MIL-STD-202, Method 210, Cond. B

MIL-STD-202, Method 106

MIL-STD-202, Method 211, Cond. C

MIL-STD-202, Method 215

MIL-STD-202, Method 208

MIL-STD-883, Method 3015, Class 1HBM 0 to 1,999V

J-STD-020, MSL=1

Please contact Q-Tech for higher shock requirements

Q-TECH Corporation - 10150 W. Jefferson Boulevard, Culver City 90232 - Tel: 310-836-7900 - Fax: 310-836-2157 - www.q-t ec h.com

QPDS-0139 (Revision -, October 2018)

5 of 7

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