QS78L15-150.000MHZ - Q-TECH Corporation

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

QT78 SERIES

HIGH RELIABILITY MINIATURE CRYSTAL CLOCK OSCILLATORS

1.8 to 5.0Vdc - 15kHz to 150MHz

Q-TECH

CORPORATION

QT78 (Revision H, January 2011) (ECO #10085)

Applications

• Designed to meet today’s requirements for low

voltage applications

• Wide military clock applications

• Smart munitions

• Navigation

• Industrial controls

• Microcontroller driver

0.170 MAX.

0.018±.003

(0.46±0.08)

(4.318 MAX.)

0.550±.0.005

(13.970±0.13)

0.350±0.005

(8.89±0.13)

0.100±.005

0.200±.005

(2.54±0.13)

(5.080±0.13)

(7.620±0.13)

(9.525 max.)

P/N

FREQ.

D/C S/N

Q-TECH

.130 MAX.

0.300±.005

0.375 max.

3.302 MAX.

Package Specifications and Outline

Dimensions are in inches (mm)

Pin No.

Function

TRISTATE or NC

GND/CASE

OUTPUT

VDD

0.39

(9.91)

0.13

(3.30)

0.13

(3.30)

0.07

(1.78)

0.20

(5.08)

0.27

(6.86)

• Package material: 90% AL2O3

• Lead material: Kovar

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

Nickel Underplate: 100μ ~ 250μ inches

• Weight: 1.1g typ., 3.0g max.

Description

Q-Tech’s surface-mount QT78 Series oscillators consist

of an IC 5Vdc, 3.3Vdc, 2.5Vdc, 1.8Vdc clock square

wave generator and a round AT high-precision quartz

crystal built in a rugged surface-mount ceramic J-lead

miniature package.

Features

• Made in the USA

• ECCN: EAR99

• DFARS 252-225-7014 Compliant:

Electronic Component Exemption

• USML Registration # M17677

• Available as QPL MIL-PRF-55310/27, /28, and /30

• Broad frequency range from 15kHz to 150MHz

• Rugged 4 point mount design for high shock and

vibration

• ACMOS, HCMOS, TTL or LVHCMOS logic

• Tri-State Output Option (D)

• Hermetically sealed ceramic SMD package

• Fundamental and 3rd Overtone designs

• Low phase noise

• Custom designs available

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

products

• RoHS compliant

Package Information

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

QT78 (Revision H, January 2011) (ECO #10085)

Electrical Characteristics

QT78 SERIES

HIGH RELIABILITY MINIATURE CRYSTAL CLOCK OSCILLATORS

1.8 to 5.0Vdc - 15kHz to 150MHz

Parameters QT78AC QT78HC QT78T QT78L QT78N QT78R

Output frequency range (Fo) 15kHz — 85.000MHz (*) 15kHz — 150.000MHz (*) 125.000kHz — 133.000MHz 125.000kHz — 100.000MHz

Supply voltage (Vdd) 5.0Vdc ± 10% 3.3Vdc ± 10% 2.5Vdc ± 10% 1.8Vdc ± 10%

Maximum Applied Voltage

(Vdd max.) -0.5 to +7.0Vdc -0.5 to +5.0Vdc

Frequency stability (∆F/∆T) See Option codes

Operating temperature (Topr) See Option codes

Storage temperature (Tsto) -62ºC to + 125ºC

Operating supply current

(Idd) (No Load)

20 mA max. - 15kHz ~ < 16MHz

25 mA max. - 16MHz ~ < 32MHz

35 mA max. - 32MHz ~ < 60MHz

45 mA max. - 60MHz ~ ≤ 85MHz

3 mA max. - 15kHz ~ < 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

3 mA max. - 125kHz ~ < 500kHz

6 mA max. - 500kHz ~ < 40MHz

15 mA max. - 40MHz ~ < 60MHz

25 mA max. - 60MHz ~ < 85MHz

35 mA max. - 85MHz ~ ≤ 133MHz

4 mA max. - 125kHz ~ < 40MHz

10 mA max. - 40MHz ~ < 50MHz

20 mA max. - 50MHz ~ < 85MHz

25 mA max. - 85MHz ~ ≤ 100MHz

Symmetry

(50% of ouput waveform or

1.4Vdc for TTL)

45/55% max. - 15kHz ~ < 15MHz

40/60% max. - 15 ~ ≤ 85MHz

(Tighter symmetry available)

45/55% max. - 15kHz ~ < 15MHz

40/60% max. - 15 ~ ≤ 150MHz

(Tighter symmetry available)

45/55% max. - 125kHz ~ < 15MHz

40/60% max. - 15 ~ ≤ 133MHz

(Tighter symmetry available)

45/55% max. - 125kHz~ < 15MHz

40/60% max. - 15 ~ ≤ 100MHz

(Tighter symmetry available)

Rise and Fall times

(with typical load)

6ns max. - Fo < 30MHz

3ns max. - Fo ≥ 30 - 85MHz

(between 10% to 90%)

7ns max. - Fo < 30MHz

3ns max. - Fo ≥ 30 - 85MHz

(between 10% to 90%)

5ns max. - Fo < 30MHz

3ns max. - Fo ≥ 30 - 85MHz

(between 0.8V to 2.0V)

6ns max. - 15kHz ~ < 40MHz

3ns max. - 40 ~ ≤ 150MHz

(between 10% to 90%)

5ns max. - 125kHz ~ < 40MHz

3ns max. - 40 ~ ≤ 133MHz

(between 10% to 90%)

5ns max. - 125kHz ~ < 40MHz

3ns max. - 40 ~ ≤ 100MHz

(between 10% to 90%)

Output Load

15pF // 10kohms

50pF max. or 10TTL

for (Fo < 60MHz)

30pF max. or 6TTL

for (Fo ≥ 60MHz)

15pF // 10kohms

(2LSTTL)

10TTL (Fo < 60MHz)

6TTL (Fo ≥ 60MHz)

15pF // 10kohms

(30pF max. for F ≤ 50MHz)

15pF // 10kohms

Start-up time (Tstup) 5ms max.

Output voltage (Voh/Vol) 0.9 x Vdd min.; 0.1 x Vdd max. 2.4V min.; 0.4V max. 0.9 x Vdd min.; 0.1 x Vdd max.

Output Current (Ioh/Iol) ± 24mA max. ± 8mA max. -1.6 mA/TTL

+40 µA/TTL

± 4mA max.

Enable/Disable

Tristate function Pin 1

VIH ≥ 2.2V Oscillation;

VIL ≤ 0.8V High Impedance

VIH ≥ 0.7 x Vdd Oscillation;

VIL ≤ 0.3 x Vdd High Impedance

Jitter RMS 1σ (at 25ºC) 8ps typ. - < 40MHz

5ps typ. - ≥ 40MHz

15ps typ. - < 40MHz

8ps typ. - ≥ 40MHz

Aging (at 70ºC) ± 5ppm max. first year / ± 2ppm max. per year thereafter

(*) Frequency as low as 1kHz without tristate function available. Contact Q-Tech for details.

Q-TECH

CORPORATION

Output frequency

Frequency vs. Temperature Code:

1 = ± 100ppm at 0ºC to +70ºC

4 = ± 50ppm at 0ºC to +70ºC

5 = ± 25ppm at -20ºC to +70ºC

6 = ± 50ppm at -55ºC to +105ºC

9 = ± 50ppm at -55ºC to +125ºC

10 = ± 100ppm at -55ºC to +125ºC

11 = ± 50ppm at -40ºC to +85ºC

12 = ± 100ppm at -40ºC to +85ºC

14 = ± 20ppm at -20ºC to +70ºC

15 = ± 25ppm at -40ºC to +85ºC

T = Standard

S = Solder Dip (*) Output frequency

Frequency vs. Temperature Code:

1 = ± 100ppm at 0ºC to +70ºC

4 = ± 50ppm at 0ºC to +70ºC

5 = ± 25ppm at -20ºC to +70ºC

6 = ± 50ppm at -55ºC to +105ºC

9 = ± 50ppm at -55ºC to +125ºC

10 = ± 100ppm at -55ºC to +125ºC

11 = ± 50ppm at -40ºC to +85ºC

12 = ± 100ppm at -40ºC to +85ºC

14 = ± 20ppm at -20ºC to +70ºC

15 = ± 25ppm at -40ºC to +85ºC

Screening Options:

Blank=No Screening

M=Per MIL-PRF-55310, Level B

Tristate Option

Blank = No Tristate

D = Tristate

T = Standard

S = Solder Dip (*) Output frequency

Frequency vs. Temperature Code:

1 = ± 100ppm at 0ºC to +70ºC

4 = ± 50ppm at 0ºC to +70ºC

5 = ± 25ppm at -20ºC to +70ºC

6 = ± 50ppm at -55ºC to +105ºC

9 = ± 50ppm at -55ºC to +125ºC

10 = ± 100ppm at -55ºC to +125ºC

11 = ± 50ppm at -40ºC to +85ºC

12 = ± 100ppm at -40ºC to +85ºC

14 = ± 20ppm at -20ºC to +70ºC

15 = ± 25ppm at -40ºC to +85ºC

Screening Options:

Blank=No Screening

M=Per MIL-PRF-55310, Level B

Tristate Option

Blank = No Tristate

D = Tristate

T = Standard

S = Solder Dip (*) Output frequency

Frequency vs. Temperature Code:

1 = ± 100ppm at 0ºC to +70ºC

4 = ± 50ppm at 0ºC to +70ºC

5 = ± 25ppm at -20ºC to +70ºC

6 = ± 50ppm at -55ºC to +105ºC

9 = ± 50ppm at -55ºC to +125ºC

10 = ± 100ppm at -55ºC to +125ºC

11 = ± 50ppm at -40ºC to +85ºC

12 = ± 100ppm at -40ºC to +85ºC

14 = ± 20ppm at -20ºC to +70ºC

15 = ± 25ppm at -40ºC to +85ºC

Screening Options:

Blank=No Screening

M=Per MIL-PRF-55310, Level B

Tristate Option

Blank = No Tristate

D = Tristate

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

QT78 SERIES

HIGH RELIABILITY MINIATURE CRYSTAL CLOCK OSCILLATORS

1.8 to 5.0Vdc - 15kHz to 150MHz

Q-TECH

CORPORATION

QT78 (Revision H, January 2011) (ECO #10085)

Packaging Options Other Options Available For An Additional Charge

Ordering Information

Frequency stability vs. temperature codes may not be available in all frequencies.

For Non-Standard requirements, contact Q-Tech Corporation at Sales@Q-Tech.com

Specifications subject to change without prior notice.

• Standard packaging in anti-static plastic tube (60pcs/tube)

• Tape and Reel (1,000pcs/reel) is available for an additional

charge.

•(*) Hot Solder Dip Sn60 per MIL-PRF 55310

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

5.0Vdc 3.3Vdc

2.5Vdc 1.8Vdc

QT78HCD9M-85.000MHz

QT78 HC D9M-85.000MHz

Sample part number

QT78LD6M-150.000MHz

QT78 LD6M-150.000MHz

Sample part number

QT78ND12M-133.000MHz

QT78 ND12 M-133.000MHz

Sample part number

QT78RD1M-100.000MHz

QT78 RD1 M-100.000MHz

Sample part number

T = Standard

S = Solder Dip (*)

Screening Options:

Blank=No Screening

M=Per MIL-PRF-55310, Level B

Tristate Option

Blank = No Tristate

D = Tristate

Logic:

AC = ACMOS

HC = HCMOS

T = TTL

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

QT78 SERIES

HIGH RELIABILITY MINIATURE CRYSTAL CLOCK OSCILLATORS

1.8 to 5.0Vdc - 15kHz to 150MHz

Q-TECH

CORPORATION

QT78 (Revision H, January 2011) (ECO #10085)

Reflow Profile Embossed Tape and Reel Information For QT78

Environmental Specifications

The five transition periods for the typical reflow process are:

• Preheat

• Flux activation

• Thermal equalization

• Reflow

• Cool down

0 20 40 60 80 100 120 140 160 180 200 220 240 260 280 300 320 340 360 380 400 420 Time (s)

100

125

150

175

200

225

250

TEMP(*C)

60s min.

120s max.

60s min.

120s max.

225º min.

240º max.

60s min.

150s max.

240º

Ramp down (6ºC/s Max)

Ramp up (3ºC/s Max)

TYPICAL REFLOW PROFILE FOR Sn-Pb ASSEMBLY

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

Reel size vs. quantity:

FEEDING (PULL) DIRECTION

ø13.0±0.5

2.5

4.80±0.1

5º MAX

ø1.5

2.0

1.75±0.1

0.3±.005 ø1.5

2.0±0.1

5.5±0.1

10.01±0.1

4.0±0.1

ø178±1

ø330±1

24.0±0.3

16±0.1

14.53

±0.1

120º

Reel size (Diameter in mm)

Qty per reel (pcs)

178

250

330

1,000

Q-Tech Standard Screening/QCI (MIL-PRF55310) is available for all of our QT78 Products. Q-Tech can also customize screening

and test procedures to meet your specific requirements. The QT78 product is designed and processed to exceed the following test

conditions:

Environmental Test Test Conditions

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

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

Seal: Fine and Gross Leak MIL-STD-883, Method 1014, Cond. A and C

Burn-in 160 hours, 125°C with load

Aging 30 days, 70°C, ±1.5ppm max

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

Shock, non operating MIL-STD-202, Method 213, Cond. I (See Note 1)

Thermal shock, non operating MIL-STD-202, Method 107, Cond. B

Ambient pressure, non operating MIL-STD-202, 105, Cond. C, 5 minutes dwell time minimum

Resistance to solder heat MIL-STD-202, Method 210, Cond. B

Moisture resistance MIL-STD-202, Method 106

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

Resistance to solvents MIL-STD-202, Method 215

Solderability MIL-STD-202, Method 208

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

Moisture Sensitivity Level J-STD-020, MSL=1

Note 1: Additional shock results successfully passed on 16MHz, 40MHz, and 80MHz

• Shock 850g peak, half-sine, 1 ms duration (MIL-STD-202, Method 213, Cond. D modified)

• Shock 1,500g peak, half-sine, 0.5ms duration (MIL-STD-883, Method 2002, Cond. B)

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-tech.com

QT78 SERIES

HIGH RELIABILITY MINIATURE CRYSTAL CLOCK OSCILLATORS

1.8 to 5.0Vdc - 15kHz to 150MHz

Q-TECH

CORPORATION

QT78 (Revision H, January 2011) (ECO #10085)

Vdd

GND

0.1xVdd

0.9xVdd

VOH

VOL

Tr Tf

0.5xVdd

SYMMETRY = x 100%

Output Waveform (Typical)

Frequency vs. Temperature Curve

Test Circuit

Output

Ground

0.1µF

15pF

Tristate Function

Power

supply 10k

Vdc

(*)

0.01µF

QT78

(*) CL includes probe and jig capacitance

Typical test circuit for CMOS logic

Frequency-Temperature Curves QT78RD-70MHz 1.8Vdc

-40

-30

-20

-10

-55 -50 -45 -40 -35 -30 -25 -20 -15 -10 -5 0510 15 20 25 30 35

Temp (ºC)

PPM

40 45 50 55 60 65 70 75 80 85 90 95 100 105 110 115 120 125

45º 45º

Hybrid Case

Substrate

Die

D/A epoxy

Heat

Die

D/A epoxy Substrate D/A epoxy Hybrid Case

R2 R3 R4 R5

Thermal Characteristics

JA JC CA

Die

(Figure 1)

(Figure 2)

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.

The heat transfer model in a hybrid package is described in

figure 1.

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 total thermal resistance is calculated by summing the

thermal resistances of each material in the thermal path

between the device and hybrid case.

RT = R1 + R2 + R3 + R4 + R5

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

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

QT78 SERIES

HIGH RELIABILITY MINIATURE CRYSTAL CLOCK OSCILLATORS

1.8 to 5.0Vdc - 15kHz to 150MHz

Q-TECH

CORPORATION

QT78 (Revision H, January 2011) (ECO #10085)

Phase noise is measured in the frequency domain, and is expressed as a ratio of signal power to noise power measured in a 1Hz

bandwidth at an offset frequency from the carrier, e.g. 10Hz, 100Hz, 1kHz, 10kHz, 100kHz, etc. Phase noise measurement is made

with an Agilent E5052A Signal Source Analyzer (SSA) with built-in outstanding low-noise DC power supply source. The DC source

is floated from the ground and isolated from external noise to ensure accuracy and repeatability.

In order to determine the total noise power over a certain frequency range (bandwidth), the time domain must be analyzed in the

frequency domain, and then reconstructed in the time domain into an rms value with the unwanted frequencies excluded. This may be

done by converting L(f) back to Sφ(f) over the bandwidth of interest, integrating and performing some calculations.

The value of RMS jitter over the bandwidth of interest, e.g. 10kHz to 20MHz, 10Hz to 20MHz, represents 1 standard deviation of

phase jitter contributed by the noise in that defined bandwidth.

Figure below shows a typical Phase Noise/Phase jitter of a QT78AC6, 5.0Vdc, 80MHz clock at offset frequencies 10Hz to 5MHz, and

phase jitter integrated over the bandwidth of 12kHz to 1MHz.

Phase Noise and Phase Jitter Integration

Period Jitter

As data rates increase, effects of jitter become critical with

its budgets tighter. Jitter is the deviation of a timing event of

a signal from its ideal position. Jitter is complex and is

composed of both random and deterministic jitter

components. Random jitter (RJ) is theoretically unbounded

and Gaussian in distribution. Deterministic jitter (DJ) is

bounded and does not follow any predictable distribution.

DJ is also referred to as systematic jitter. A technique to

measure period jitter (RMS) one standard deviation (1σ) and

peak-to-peak jitter in time domain is to use a high sampling

rate (>8G samples/s) digitizing oscilloscope. Figure shows

an example of peak-to-peak jitter and RMS jitter (1σ) of a

QT78AC-24MHz, at 5.0Vdc.

RMS jitter (1σ): 5.37ps Peak-to-peak jitter: 43ps

Symbol

Definition

∫L(f) Integrated single side band phase noise (dBc)

Sφ (f)=(180/Π)x√2 ∫L(f)df Spectral density of phase modulation, also known as RMS phase error (in degrees)

RMS jitter = Sφ (f)/(fosc.360°) Jitter(in seconds) due to phase noise. Note Sφ (f) in degrees.