MtronPTI reserves the right to make changes to the product(s) and service(s) described herein without notice. No liability is assumed as a result of their use or application.
Please see
www.mtronpti.com
for our complete offering and detailed datasheets. Contact us for your application specific requirements: MtronPTI
1-800-762-8800.
Rev: 10/14/2013
M630x Series
5x7 mm, 3.3/2.5/1.8 Volt, LVPECL/LVDS/CML/CMOS, TCXO/TCVCXO
Parameter
Frequency Range
Initial Accuracy
Frequency Stability
Frequency Vs. Aging
Frequency Vs. Supply Voltage
Frequency Vs. Reflow
Frequency Vs. Load
Operating Temperature
Storage Temperature
Operating Voltage
Symbol
F
R
F
I
∆F
T
/F
∆F
TIME
/F
∆F
VDD
/F
∆F
LOAD
/F
T
A
T
STG
V
CC
/V
S
/V
DD
Min.
Typ.
Max.
50
1400
50
135
-1
+1
See Ordering Information
-3
-1
±0.40
±0.75
±0.20
See Ordering Information
-55
3.135
2.375
1.71
3.3
2.5
1.8
+125
3.465
2.625
1.89
125
100
110
90
0.35
6
+3
+1
Units
MHz
MHz
ppm
ppm
ppm
ppm
ppm
ppm
ppm
°C
°C
V
V
V
mA
mA
mA
mA
ns
ns
V
% V
DD
V
% V
DD
V
%
%
%
Conditions/Notes
LVPECL, LVDS, CML (See Note 1)
CMOS
@ +25 °C
(Fmax - Fmin)/2 (See Note 2)
First year
Thereafter (per year)
5% voltage variation
2 reflows max.
5% supply voltage variation
Operating Current
I
CC
Rise/Fall Time
t
R
/t
F
V
OH
V
OL
V
CM
t
DC
1.2
45
45
45
0.7
±5
0.18
0.25
0.30
V
CC
- 1.02
90
Electrical Specifications
Logic “1” Level
Logic “0” Level
Common Mode Output Voltage
Symmetry (Duty Cycle)
V
CC
- 1.63
10
55
55
55
1.2
M6300
M6301
M6302
LVPECL
LVDS
CML
CMOS
LVPECL, LVDS, CML
CMOS
LVPECL
CMOS
LVPECL
CMOS
LVDS
@ 50% V
DD
(CMOS)
Output Voltage Level
Tuning Range
Voltage Control Range
0.95
V
C
Output Skew
Output Load
0.90
1.62
1.25
2.25
1.65
3.00
20
15
20
50 Ω to (V
CC
- 2)
V
DC
100 Ω Differential
15 pF
0.5
0.5
Enable/Disable Function
(Option B or G)
Enable/Disable Function
(Option S or M)
Phase Noise (Typical)
@ 622.080 MHz (LVPECL)
@ 100.000 MHz (HCMOS)
@ 50.000 MHZ (HCMOS)
80
80
10 Hz
-60
-70
-77
100 Hz
-90
-103
-109
1 kHz
-120
-123
-129
10 kHz
-127
-131
-137
@ 50% of waveform (LVPECL)
@ 1.25 V (LVDS)
V
pk-pk
CML
ppm VCTCXO only (See Note 3)
V
@ 1.8 V supply (VCTCXO only - Pad 2)
V
@ 2.5 V supply (VCTCXO only - Pad 2)
V
@ 3.3 V supply (VCTCXO only - Pad 2)
ps
LVPECL
ps
CML
ps
LVDS
LVPECL (See Note 4)
LVDS, CML (See Note 4)
CMOS (See Note 4)
%
Output Enabled
V
Output Disabled
V
Output Enabled
%
Output Disabled
100 kHz Offset from carrier
-133 dBc/Hz
-136 dBc/Hz
-141 dBc/Hz
Note
Note
Note
Note
Per MIL-STD-202, Method 213, Condition C
Shock
Per MIL-STD-202, Methods 201 & 204
Vibration
Per EIAJ-STD-002
Solderability
-8
Hermeticity
1 X 10 atm cc/sec of helium (Crystal only)
Per MIL-STD-883, Method 1011, Condition A
Thermal Shock
Per MIL-STD-883, Method 1010, Condition B
Thermal Cycle
1: Contact factory for frequencies over 945 MHz.
2: Contact factory for less than ±1 ppm frequency stability.
3: Contact factory for other tuning range options.
4: Refer to the load circuit diagram in this data sheet.
MtronPTI reserves the right to make changes to the product(s) and service(s) described herein without notice. No liability is assumed as a result of their use or application.
Environmental
Please see
www.mtronpti.com
for our complete offering and detailed datasheets. Contact us for your application specific requirements: MtronPTI
1-800-762-8800.
Load Circuit Diagrams
Lead Free Solder Profile
MtronPTI reserves the right to make changes to the product(s) and service(s) described herein without notice. No liability is assumed as a result of their use or application.
Please see
www.mtronpti.com
for our complete offering and detailed datasheets. Contact us for your application specific requirements: MtronPTI
I have been working in the embedded field for almost 2 years. I have been working on drivers all day long. I am tired of dealing with gpio, boot room, nand nor circuit diagrams, registers, etc. Now I ...
This book is divided into two parts: radar main components and measurement methods. The former includes radar transmitters, radar receivers and radar terminals. The book explains their composition, wo...
Introduction to the design method of non-isolated buck power supply Non-isolated buck power supply is a commonly used power supply structure, accounting for more than 90% of fluorescent lamp power sup...
Designers implement current sensing for system protection and monitoring by placing a very small "shunt" resistor in series with the load and a current sense amplifier or op amp between the two. While...
Hello everyone, I would like to ask you how to implement the status prompt under evc, for example, when I am uploading a file, there will be a window prompting that it is uploading, and when the trans...
The problem of dynamic sealing of equipment always exists with the operation of the equipment. Today, we have specially sorted out the various commonly used sealing forms, usage scope and character...[Details]
A vacuum eutectic furnace is a critical piece of equipment used in the manufacturing and processing of various materials, particularly in the fields of microelectronics and nanotechnology. One of t...[Details]
Is pure electric vehicles a false proposition for long-distance driving? At least from my personal perspective, based on current technological and infrastructure standards, I believe so. Below, I'l...[Details]
Topics: Bring Your Own Device (BYOD) trends; the impact of using employees' own mobile devices to control access to work facilities and equipment on information security; and ways to securely imple...[Details]
Robotics
has become
LiDAR
's "second growth curve."
While LiDAR was still battling with its "pure vision" rivals in the automotive field, another field ignited the demand f...[Details]
When discussing autonomous driving technology, there are often two extremes: on the one hand, there's the vision of "fully autonomous driving," while on the other, there's concern about potential s...[Details]
The all-new MG4 was recently officially announced on the Ministry of Industry and Information Technology's (MIIT) new vehicle announcement. The all-new MG4's semi-solid-state battery version addres...[Details]
According to foreign media reports, Nissan Motor has recently reached a cooperation with US battery technology company LiCAP Technologies to jointly promote the research and development of next-gen...[Details]
Electric vehicles are now widespread, but they've brought with them a host of problems, the most prominent of which is charging. Small electric vehicles (EVs) are a new form of transportation in a ...[Details]
With the continuous development of the industrial automation industry, we are seeing an increasing number of intelligent devices using flexible, efficient, and precise robotic arms to p...[Details]
According to Nikkei, a survey found that global electric vehicle battery supply is expected to reach more than three times the required quantity due to
cooling
demand for electric vehicles,...[Details]
A patent disclosed by Ford proposes replacing traditional segmented side curtain airbags with integrated full-width side curtain airbags that span the side of the vehicle and can be deployed simult...[Details]
On August 21st, BYD announced the launch of its next-generation "Little White Pile" product, the "Lingchong"
charging
pile
, which is now available for general sale. This charging pile feat...[Details]
Tiantai Robot's official Weibo account announced on the evening of August 20 that Tiantai Robot Co., Ltd., together with strategic partners including Shandong Future Robot Technology Co., Ltd., Sha...[Details]
In the field of intelligent driving, regulations are becoming increasingly stringent, and the technical threshold continues to rise. Especially after the traffic accident in March 2025, the Ministr...[Details]
Embedded System
京公网安备 11010802033920号
EEWORLD
