QT93W and QT93P SERIES
Q-TECH
CORPORATION
HIGH-RELIABILITY LVPECL OR LVDS MINIATURE CLOCK OSCILLATORS
2.5 to 3.3Vdc - 40MHz to 160MHz
Description
Q-Tech’s surface-mount QT93 series oscillators consist of
a 2.5Vdc and 3.3Vdc differential PECL or LVDS output
oscillator IC and a round AT high-precision quartz crystal
built in a rugged surface-mount ceramic miniature
package. It was designed to be replaceable and
retrofitable into the footprint of a 7 x 5mm COTS
LVPECL or LVDS oscillator.
Features
• Made in the USA
• ECCN: EAR99
• DFARS 252-225-7014 Compliant:
Electronic Component Exemption
• USML Registration # M17677
• Smallest AT round crystal package ever designed
• Broad frequency range from 40MHz to 160MHz
• Able to meet 36000G shock per ITOP 1-2-601
• Rugged 4 point mount design for high shock and
vibration
• Differential LVPECL or LVDS output
• Tri-State Output
• Hermetically sealed ceramic SMD package
• 3rd Overtone designs, no sub-harmonics
• Low phase noise, low noise coupling, low emissions
• Custom designs available
• Q-Tech does not use pure lead or pure tin in its
products
• RoHS compliant
Package Specifications and Outline
0.350±.0.005
(8.89±0.13)
6
5
4
Q-TECH
P/N
FREQ.
D/C S/N
Pin No.
0.290±0.005
(7.37±0.13)
1
2
3
4
5
6
Function
TRISTATE
OUTPUT
VCC
GND
NC
1
2
3
0.100±.005
(2.54±0.13)
COMP. OUTPUT
0.200±.005
(5.08±0.13)
0.190 MAX.
(4.826 MAX.)
0.018±.003
(.457±0.076)
0.071
(1.8)
0.315±0.005
(8.00±0.13)
0.130
(3.3)
0.071
(1.81)
Applications
•
•
•
•
•
•
•
•
0.055±.005
(1.396±0.13)
0.008
(.203)
0.110±.005
(2.794±0.13)
SONET/SDH
Fibre channel
Gun launched munitions and systems
Applications required high data transmission
throughputs
Clock generation and distribution
Audio/Video signal processing
Broadband access
Ethernet, Gigabit Ethernet
0.2
(5.08)
Dimensions are in inches (mm)
Package material: 90% AL2O3
Lead material: Kovar
Lead finish:
• Gold Plated: 50µ ~ 80µ inches
• Nickel Underplate: 100µ ~ 250µ inches
Q-TECH Corporation - 10150 W. Jefferson Boulevard, Culver City 90232 - Tel: 310-836-7900 - Fax: 310-836-2157 - www.q-t ec h.com
QT93W & P (Revision -, August 2008)
1
QT93W and QT93P SERIES
Electrical Characteristics
Parameters
Supply voltage (Vcc)
Output frequency range (Fo)
CORPORATION
Q-TECH
HIGH-RELIABILITY LVPECL or LVDS MINIATURE CLOCK OSCILLATORS
2.5 to 3.3Vdc - 40MHz to 160MHz
QT93LW
3.3Vdc ± 5%
(LVDS Output)
QT93NW
2.5Vdc ± 5%
40MHz — 160.00MHz (*)
See option codes
-62ºC to + 150ºC
See option codes
QT93LP
3.3Vdc ± 5%
(LVPECL Output)
QT93NP
2.5Vdc ± 5%
Frequency stability (∆F/∆T)
Storage temperature (Tsto)
Operating temperature (Topr)
Operating supply current
(Icc)
80mA max.
(45mA typ. at 125MHz)
65mA max.
Output Load
Rise and Fall times
(measured between 20% to 80% Vcc)
Symmetry
(measured at 50% output level )
80mA max.
(45mA typ. at 100MHz)
45/55% max.
600ps max.
(Connected between Out and Comp. Out)
VOH = 1.45V typ., 1.65V max.
VOL = 1.10V typ., 0.90V min.
100Ω
(Requires termination)
Start-up time (Tstup)
2ms max.
(Connected between each Output and Vcc -2Vdc)
VOH = 2.215V min.; 2.420V max.
VOL = 1.47V min.; 1.745V max.
VOH = 1.415V min.; 1.76V max.
VOL = 0.67 min.; 1.195V max.
50Ω to Vcc -2Vdc (or Thevenin equivalent)
1.0ns max. (600ps typ.)
Output voltage (Voh/Vol)
Enable/Disable Tristate function
(see note 1)
Jitter
(*) Higher frequencies are available. Please contact Q-Tech for details.
RMS Phase jitter (integrated 12kHz — 40MHz): 1ps max.
Total jitter: 30ps peak-to-peak
Pin 1: Open or VIH ≥ 0.7*Vcc Oscillation
VIL ≤ 0.3*Vcc High Z
Note 1: There is a built-in OE pull-up resistor which resistance value changes in response to the input level (High or Low) to save power consumption.
Q-TECH Corporation
QT93W & P (Revision -, August 2008)
-
10150 W. Jefferson Boulevard, Culver City 90232
-
Tel: 310-836-7900 - Fax: 310-836-2157
-
www.q-t ec h.c om
2
QT93W and QT93P SERIES
Q-TECH
Ordering Information
CORPORATION
HIGH-RELIABILITY LVPECL OR LVDS MINIATURE CLOCK OSCILLATORS
2.5 to 3.3Vdc - 40MHz to 160MHz
QT93LW — XX — M — 155.520MHz
3.3Vdc LVDS
Screened to
MIL-PRF-55310,level B
1
4
5
6
9
10
11
12
14
15
=
=
=
=
=
=
=
=
=
=
± 100ppm at
± 50ppm at
± 25ppm at
± 50ppm at
± 50ppm at
± 100ppm at
± 50ppm at
± 100ppm at
± 20ppm at
± 25ppm at
(Left blank if no screening)
Output frequency
QT93NW — XX — M —125.000MHz
2.5Vdc LVDS
0ºC
0ºC
-20ºC
-55ºC
-55ºC
-55ºC
-40ºC
-40ºC
-20ºC
-40ºC
to
to
to
to
to
to
to
to
to
to
+70ºC
+70ºC
+70ºC
+105ºC
+125ºC
+125ºC
+85ºC
+85ºC
+70ºC
+85ºC
1
4
5
6
9
10
11
12
14
15
=
=
=
=
=
=
=
=
=
=
± 100ppm at
± 50ppm at
± 25ppm at
± 50ppm at
± 50ppm at
± 100ppm at
± 50ppm at
± 100ppm at
± 20ppm at
± 25ppm at
(Left blank if no screening)
Screened to
MIL-PRF-55310,level B
0ºC
0ºC
-20ºC
-55ºC
-55ºC
-55ºC
-40ºC
-40ºC
-20ºC
-40ºC
to
to
to
to
to
to
to
to
to
to
+70ºC
+70ºC
+70ºC
+105ºC
+125ºC
+125ºC
+85ºC
+85ºC
+70ºC
+85ºC
Output frequency
QT93LP — XX — M — 106.250MHz
3.3Vdc LVPECL
Screened to
MIL-PRF-55310,level B
1
4
5
6
9
10
11
12
14
15
=
=
=
=
=
=
=
=
=
=
± 100ppm at
± 50ppm at
± 25ppm at
± 50ppm at
± 50ppm at
± 100ppm at
± 50ppm at
± 100ppm at
± 20ppm at
± 25ppm at
(Left blank if no screening)
Output frequency
QT93NP — XX — M — 100.000MHz
2.5Vdc LVPECL
0ºC
0ºC
-20ºC
-55ºC
-55ºC
-55ºC
-40ºC
-40ºC
-20ºC
-40ºC
to
to
to
to
to
to
to
to
to
to
+70ºC
+70ºC
+70ºC
+105ºC
+125ºC
+125ºC
+85ºC
+85ºC
+70ºC
+85ºC
1
4
5
6
9
10
11
12
14
15
=
=
=
=
=
=
=
=
=
=
± 100ppm at
± 50ppm at
± 25ppm at
± 50ppm at
± 50ppm at
± 100ppm at
± 50ppm at
± 100ppm at
± 20ppm at
± 25ppm at
(Left blank if no screening)
Screened to
MIL-PRF-55310,level B
0ºC
0ºC
-20ºC
-55ºC
-55ºC
-55ºC
-40ºC
-40ºC
-20ºC
-40ºC
to
to
to
to
to
to
to
to
to
to
+70ºC
+70ºC
+70ºC
+105ºC
+125ºC
+125ºC
+85ºC
+85ºC
+70ºC
+85ºC
Output frequency
Packaging Options
For Non-Standard requirements, contact Q-Tech Corporation at Sales@Q-Tech.com
• Solder Dip Sn/Pb 60/40%
• P. I. N. D. test
Frequency stability vs. temperature codes may not be available in all frequencies.
• Standard packaging in anti-static plastic tube (60pcs/tube)
• Tape and Reel (800pcs/reel) is available for an additional
charge.
Other Options Available For An Additional Charge
Specifications subject to change without prior notice.
Q-TECH Corporation - 10150 W. Jefferson Boulevard, Culver City 90232 - Tel: 310-836-7900 - Fax: 310-836-2157 - www.q-t ec h.com
QT93W & P (Revision -, August 2008)
3
QT93W and QT93P SERIES
Q-TECH
Output Waveform (Typical)
CORPORATION
HIGH-RELIABILITY LVPECL OR LVDS MINIATURE CLOCK OSCILLATORS
2.5 to 3.3Vdc - 40MHz to 160MHz
Test Circuit
Vcc
Vcc
Q
50
Vcc
130
Q
82
Vcc
6
5
QT93LP
4
3
50
Vcc-2V
Q
6
5
QT93LP
3
82
4
130
Q
Typical start-up time of an LVPECL 3.3Vdc 200MHz at -55ºC 0.833ms
Vcc-2V
STANDARD TERMINATION LVPECL
THEVENIN EQUIVALENT 3.3V LVPECL
Vcc
Vcc
250
Q
62
Vcc
Vcc
Q
100
6
5
QT93LW
Q
4
3
6
5
QT93NP
4
3
250
VOH
Q
VOL
62
Reflow Profile
TEMP(*C)
Typical plot of an LVPECL 3.3Vdc 64MHz terminated with Thevenin equivalent
THEVENIN EQUIVALENT 2.5V LVPECL
LVDS TERMINATION
The Tristate function on pin 1 has a built-in pull-up resistor so it can be left float-
ing or tied to Vcc without deteriorating the electrical performance.
TYPICAL REFLOW PROFILE FOR Sn-Pb ASSEMBLY
Embossed Tape and Reel Information
FEEDING (PULL) DIRECTION
2.0±0.1
1.75±0.1
Ramp down (6ºC/s Max)
Ramp up (3ºC/s Max)
250
225
200
175
150
240º
0.3±.005
ø1.5
4.0±0.1
225º min.
240º max.
5.5±0.1
9.271
±0.1
ø1.5
16±0.1
7.747±0.1
26
2.0
60s min.
150s max.
60s min.
120s max.
5º MAX
125
100
75
50
25
60s min.
120s max.
4.699±0.1
0
Environmental and Mechanical Specifications
Constant acceleration
Seal Gross Leak
Vibration sinusoidal
Shock, non operating
Solderability
0
20
40
60
80 100 120 140 160 180 200 220 240 260 280 300 320 340 360 380 400 420
Time (s)
MIL-STD-883, Method 2001, Cond. A, Y1
MIL-STD-883, Method 1014, Cond. C
MIL-STD-202, Method 204, Cond. D
MIL-STD-202, Method 213, Cond. I
MIL-STD-202, Method 215
MIL-STD-202, Method 208
Resistance to solder heat MIL-STD-202, Method 210, Cond. C
Resistance to solvents
Dimensions are in mm. Tape is compliant to EIA-481-A.
Reel size (Diameter in mm)
178
120º
Qty per reel (pcs)
1,000
Q-TECH Corporation - 10150 W. Jefferson Boulevard, Culver City 90232 - Tel: 310-836-7900 - Fax: 310-836-2157 - www.q-t ec h.com
QT93W & P (Revision -, August 2008)
ø178±1
or
ø330±1
Environmental Test
Test Conditions
Temperature cycling
MIL-STD-883, Method 1010, Cond. B
ø13.0±0.5
2.5
4
24.0±0.3
QT93W and QT93P SERIES
Q-TECH
CORPORATION
Phase Noise and Phase Jitter Integration
HIGH-RELIABILITY LVPECL OR LVDS MINIATURE CLOCK OSCILLATORS
2.5 to 3.3Vdc - 40MHz to 160MHz
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 meas-
urement is made with an Agilent E5052A Signal Source Ana-
lyzer (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 repeatabil-
ity.
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 frequen-
cies excluded. This may be done by converting L(f) back to
Sφ(f) over the bandwidth of interest, integrating and perform-
ing some calculations.
The value of RMS jitter over the bandwidth of interest, e.g.
10kHz to 20MHz, 10Hz to 20MHz, represents 1 standard devi-
ation of phase jitter contributed by the noise in that defined
bandwidth.
Figure 1 shows a typical Phase Noise/Phase jitter of a
QT93LW, 3.3Vdc, 100MHz clock at offset frequencies 10Hz
to 10MHz, and phase jitter integrated over the bandwidth of
12kHz to 20MHz.
(Figure 1)
Thermal Characteristics
The heat transfer model in a hybrid package is described in
figure 2.
D/A epoxy
Die
D/A epoxy
45º
Heat
Hybrid Case
45º
Substrate
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
R1
R2
R3
R4
R5
Die
D/A epoxy
The total thermal resistance RT (see figure 3) between the heat
source (die) to the hybrid case is the Theta Junction to Case
(Theta JC) in°C/W.
(Figure 2)
Substrate
D/A epoxy
Hybrid Case
T
CA
• Theta junction to case (Theta JC) for this product is 35°C/W.
• Theta case to ambient (Theta CA) for this part is 100°C/W.
• Theta Junction to ambient (Theta JA) is 135°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)/135 = 1.11W
A
T
C
JC
T
J
Die
JC
CA
JA
(Figure 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
QT93W & P (Revision -, August 2008)
5
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