Any frequency between 1 MHz and 110 MHz accurate to 6 decimal
places
Operating temperature from -40°C to 85°C. Refer to
SiT8918
and
SiT8920
for high temperature options
Excellent total frequency stability as low as ±20 PPM
Low power consumption of 3.6 mA typical
Programmable drive strength for improved jitter, system EMI
reduction, or driving large capacitive loads
LVCMOS/HCMOS compatible output
Industry-standard packages: 2.0 x 1.6, 2.5 x 2.0, 3.2 x 2.5, 5.0 x 3.2,
7.0 x 5.0 mm x mm
Instant samples with
Time Machine II
and
field programmable
oscillators
Pb-free, RoHS and REACH compliant
Ideal for DSC, DVC, DVR, IP CAM, Tablets, e-Books, SSD,
GPON, EPON, etc
Ideal for high-speed serial protocols such as: USB, SATA, SAS,
Firewire, 100M / 1G / 10G Ethernet, etc.
Electrical Characteristics
[1]
Parameter and Conditions
Output Frequency Range
Frequency Stability
Symbol
f
F_stab
Min.
1
-20
-25
-50
Operating Temperature Range
T_use
-20
-40
Supply Voltage
Vdd
1.62
2.25
2.52
2.7
2.97
2.25
Current Consumption
Idd
–
–
–
OE Disable Current
Standby Current
I_OD
I_std
–
–
–
–
–
Duty Cycle
Rise/Fall Time
DC
Tr, Tf
45
–
–
–
Output High Voltage
VOH
90%
Typ.
–
–
–
–
–
–
1.8
2.5
2.8
3.0
3.3
–
3.8
3.6
3.4
–
–
2.6
1.4
0.6
–
1
1.3
–
–
Max.
110
+20
+25
+50
+70
+85
1.98
2.75
3.08
3.3
3.63
3.63
4.5
4.2
3.9
4
3.8
4.3
2.5
1.3
55
2
2.5
2
–
Unit
MHz
PPM
PPM
PPM
°C
°C
V
V
V
V
V
V
mA
mA
mA
mA
mA
A
A
A
%
ns
ns
ns
Vdd
No load condition, f = 20 MHz, Vdd = 2.8V, 3.0V, 3.3V, 2.25V to 3.63V
No load condition, f = 20 MHz, Vdd = 2.5V
No load condition, f = 20 MHz, Vdd = 1.8V
Vdd = 2.5V to 3.3V, OE = GND, output is Weakly Pulled Down
Vdd = 1.8V, OE = GND, output is Weakly Pulled Down
ST = GND, Vdd = 2.8V to 3.3V, Output is Weakly Pulled Down
ST = GND, Vdd = 2.5V, Output is Weakly Pulled Down
ST = GND, Vdd = 1.8V, Output is Weakly Pulled Down
All Vdds
Vdd = 2.5V, 2.8V, 3.0V or 3.3V, 20% - 80%
Vdd =1.8V, 20% - 80%
Vdd = 2.25V - 3.63V, 20% - 80%
IOH = -4 mA (Vdd = 3.0V or 3.3V)
IOH = -3 mA (Vdd = 2.8V and Vdd = 2.5V)
IOH = -2 mA (Vdd = 1.8V)
IOL = 4 mA (Vdd = 3.0V or 3.3V)
IOL = 3 mA (Vdd = 2.8V and Vdd = 2.5V)
IOL = 2 mA (Vdd = 1.8V)
Pin 1, OE or ST
Pin 1, OE or ST
Pin 1, OE logic high or logic low, or ST logic high
Inclusive of Initial tolerance at 25°C, 1st year aging at 25°C, and
variations over operating temperature, rated power supply
voltage and load (15 pF ± 10%).
Condition
Frequency Range
Frequency Stability and Aging
Operating Temperature Range
Extended Commercial
Industrial
Contact
SiTime
for 1.5V support
Supply Voltage and Current Consumption
LVCMOS Output Characteristics
Output Low Voltage
VOL
–
–
10%
Vdd
Input Characteristics
Input High Voltage
Input Low Voltage
Input Pull-up Impedence
VIH
VIL
Z_in
70%
–
–
–
–
87
–
30%
100
Vdd
Vdd
k
2
–
–
M
Pin 1, ST logic low
Note:
1. All electrical specifications in the above table are specified with 15 pF output load at default drive strength and for all Vdd(s) unless otherwise stated.
SiTime Corporation
Rev. 1.11
990 Almanor Avenue
Sunnyvale, CA 94085
(408) 328-4400
www.sitime.com
Revised May 27, 2013
SiT8008
Low Power Programmable Oscillator
The Smart Timing Choice
The Smart Timing Choice
Electrical Characteristics
[1]
(continued)
Parameter and Conditions
Startup Time
Enable/Disable Time
Resume Time
RMS Period Jitter
RMS Phase Jitter (random)
Symbol
T_start
T_oe
T_resume
T_jitt
T_phj
Min.
–
–
–
–
–
–
–
Typ.
–
–
–
1.76
1.78
0.5
1.3
Max.
5
130
5
Jitter
3
3
0.9
2
ps
ps
ps
ps
f = 75 MHz, Vdd = 2.5V, 2.8V, 3.0V or 3.3V
f = 75 MHz, Vdd = 1.8V
f = 75 MHz, Integration bandwidth = 900 kHz to 7.5 MHz
f = 75 MHz, Integration bandwidth = 12 kHz to 20 MHz
Unit
ms
ns
ms
Condition
Measured from the time Vdd reaches its rated minimum value
f = 110 MHz. For other frequencies, T_oe = 100 ns + 3 * cycles
Measured from the time ST pin crosses 50% threshold
Startup and Resume Timing
Note:
1. All electrical specifications in the above table are specified with 15 pF output load and for all Vdd(s) unless otherwise stated.
Pin Description
Pin
Symbol
Output Enable
1
OE/ ST
Standby
2
3
4
GND
OUT
VDD
Power
Output
Power
Functionality
H or Open
[2]
: specified frequency output
L: output is high impedance. Only output driver is disabled.
H or Open
[2]
: specified frequency output
L: output is low (weak pull down). Device goes to sleep mode. Supply
current reduces to I_std.
Electrical ground
[3]
Oscillator output
Power supply voltage
[3]
GND
2
3
Top View
OE/ST
1
4
VDD
OUT
Notes:
2. A pull-up resistor of <10 k between OE/ ST pin and Vdd is recommended in high noise environment.
3. A capacitor value of 0.1 µF between Vdd and GND is recommended.
Absolute Maximum
Attempted operation outside the absolute maximum ratings of the part may cause permanent damage to the part. Actual perfor-
mance of the IC is only guaranteed within the operational specifications, not at absolute maximum ratings.
Parameter
Storage Temperature
VDD
Electrostatic Discharge
Soldering Temperature (follow standard Pb free soldering guidelines)
Junction Temperature
Min.
-65
-0.5
–
–
–
Max.
150
4
2000
260
150
Unit
°C
V
V
°C
°C
Thermal Consideration
Package
7050
5032
3225
2520
2016
JA, 4 Layer Board (°C/W)
191
97
109
117
124
JA, 2 Layer Board (°C/W)
263
199
212
222
227
JC, Bottom
(°C/W)
30
24
27
26
26
Environmental Compliance
Parameter
Mechanical Shock
Mechanical Vibration
Temperature Cycle
Solderability
Moisture Sensitivity Level
Condition/Test Method
MIL-STD-883F, Method 2002
MIL-STD-883F, Method 2007
JESD22, Method A104
MIL-STD-883F, Method 2003
MSL1 @ 260°C
Rev. 1.11
Page 2 of 11
www.sitime.com
SiT8008
Low Power Programmable Oscillator
The Smart Timing Choice
The Smart Timing Choice
Test Circuit and Waveform
[4]
Vdd
Vout
Test
Point
tr
80% Vdd
tf
4
Power
Supply
0.1µF
3
15pF
(including probe
and fixture
capacitance)
50%
20% Vdd
High Pulse
(TH)
Period
Low Pulse
(TL)
1
2
Vdd
OE/ST Function
1k
Figure 1. Test Circuit
Note:
4. Duty Cycle is computed as Duty Cycle = TH/Period.
Figure 2. Waveform
Timing Diagrams
90% Vdd, 2.5/2,8/3.3V devices
Vdd
95% Vdd, 1.8V devices
Vdd
Pin 4 Voltage
NO Glitch first cycle
ST Voltage
50% Vdd
T_resume
CLK Output
T_start
CLK Output
T_start: Time to start from power-off
T_resume: Time to resume from ST
Figure 3. Startup Timing (OE/ST Mode)
u
Vdd
50% Vdd
T_OE
CLK Output
Figure 4. Standby Resume Timing (ST Mode Only)
OE Voltage
Vdd
OE Voltage
50% Vdd
CLK Output
T_OE
HZ
T_OE: Time to re-enable the clock output
T_OE: Time to put the output drive in High Z mode
Figure 5. OE Enable Timing (OE Mode Only)
Note:
5. SiT8008 supports no runt pulses and no glitches during startup or resume.
Figure 6. OE Disable Timing (OE Mode Only)
Rev. 1.11
Page 3 of 11
www.sitime.com
SiT8008
Low Power Programmable Oscillator
The Smart Timing Choice
The Smart Timing Choice
Performance Plots
1.8
2.5
2.8
3
3.3
1.8 V
2.5 V
2.8 V
3.0 V
3.3 V
6.0
4.0
RMS period jitter (ps)
5.5
5.0
4.5
4.0
3.5
3.0
0
10
20
30
40
50
60
70
80
90
100
110
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
0
10
20
30
40
50
60
70
80
90
100
110
Idd (mA)
Frequency (MHz)
Frequency (MHz)
Figure 7. Idd vs Frequency
Figure 8. RMS Period Jitter vs Frequency
1.8 V
2.5 V
2.8 V
3.0 V
3.3 V
1.8 V
2.5 V
2.8 V
3.0 V
3.3 V
2.0
1.8
0.9
0.85
0.8
0.75
IPJ (ps)
1.6
1.4
1.2
1.0
10
30
50
70
90
110
IPJ (ps)
0.7
0.65
0.6
0.55
0.5
0.45
0.4
10
30
50
70
90
110
Frequency (MHz)
Frequency (MHz)
Figure 9. RMS Phase Jitter vs Frequency
(12 kHz to 20 MHz Integration Bandwidth)
Figure 10. RMS Phase Jitter vs Frequency
(900 kHz to 20 MHz Integration Bandwidth)
1.8 V
2.5 V
2.8 V
1.8 V
2.5 V
2.8 V
3.0 V
3.3 V
55
54
53
2.5
2.0
Duty Cycle (%)
51
50
49
48
47
46
45
0
10
20
30
40
50
60
70
80
90
100
110
Rise Time (ns)
52
1.5
1.0
0.5
0.0
-40
-15
10
35
60
85
Frequency (MHz)
Temperature (°C)
Figure 11. Duty Cycle vs Frequency
Figure 12. Rise Time vs Temperature, 20 MHz Output
Note:
6. All plots are measured with 15 pF load at room temperature, unless otherwise stated.
Rev. 1.11
Page 4 of 11
www.sitime.com
SiT8008
Low Power Programmable Oscillator
The Smart Timing Choice
The Smart Timing Choice
Programmable Drive Strength
The SiT8008 includes a programmable drive strength feature
to provide a simple, flexible tool to optimize the clock rise/fall
time for specific applications. Benefits from the programmable
drive strength feature are:
• Improves system radiated electromagnetic interference
(EMI) by slowing down the clock rise/fall time
• Improves the downstream clock receiver’s (RX) jitter by de-
creasing (speeding up) the clock rise/fall time.
• Ability to drive large capacitive loads while maintaining full
swing with sharp edge rates.
For more detailed information about rise/fall time control and
drive strength selection, see the SiTime Applications Note
section;
http://www.sitime.com/support/application-notes.
EMI Reduction by Slowing Rise/Fall Time
Figure 13 shows the harmonic power reduction as the rise/fall
times are increased (slowed down). The rise/fall times are
expressed as a ratio of the clock period. For the ratio of 0.05,
the signal is very close to a square wave. For the ratio of 0.45,
the rise/fall times are very close to near-triangular waveform.
These results, for example, show that the 11th clock harmonic
can be reduced by 35 dB if the rise/fall edge is increased from
5% of the period to 45% of the period.
10
0
trise=0.05
trise=0.1
trise=0.15
trise=0.2
trise=0.25
trise=0.3
trise=0.35
trise=0.4
trise=0.45
choose to speed up the rise/fall time to 1.68ns by then
increasing the drive strength setting on the SiT8008.
The SiT8008 can support up to 60 pF or higher in maximum
capacitive loads with up to 3 additional drive strength settings.
Refer to the
Rise/Tall Time Tables
to determine the proper
drive strength for the desired combination of output load vs.
rise/fall time
SiT8008 Drive Strength Selection
Tables 1 through 5 define the rise/fall time for a given capac-
itive load and supply voltage.
1. Select the table that matches the SiT8008 nominal supply
voltage (1.8V, 2.5V, 2.8V, 3.0V, 3.3V).
2. Select the capacitive load column that matches the appli-
cation requirement (5 pF to 60 pF)
3. Under the capacitive load column, select the desired
rise/fall times.
4. The left-most column represents the part number code for
the corresponding drive strength.
5. Add the drive strength code to the part number for ordering
purposes.
Calculating Maximum Frequency
Based on the rise and fall time data given in Tables 1 through
4, the maximum frequency the oscillator can operate with
guaranteed full swing of the output voltage over temperature
as follows:
Harmonic amplitude (dB)
-10
-20
-30
-40
-50
-60
-70
-80
1
3
5
7
9
Max Frequency =
Example 1
1
6 x (T
rise
)
Calculate f
MAX
for the following condition:
11
Harm onic num ber
• Vdd = 1.8V (Table 1)
• Capacitive Load: 30 pF
• Desired Tr/f time = 3 ns (rise/fall time part number code = E)
Part number for the above example:
SiT8008AIE12-18E-25.000000T
Figure 13. Harmonic EMI reduction as a Function of
Slower Rise/Fall Time
Jitter Reduction with Faster Rise/Fall Time
Power supply noise can be a source of jitter for the
downstream chipset. One way to reduce this jitter is to
increase rise/fall time (edge rate) of the input clock. Some
chipsets would require faster rise/fall time in order to reduce
their sensitivity to this type of jitter. The SiT8008 provides up
to 3 additional high drive strength settings for very fast rise/fall
time. Refer to the
Rise/Fall Time Tables
to determine the
proper drive strength.
High Output Load Capability
The rise/fall time of the input clock varies as a function of the
actual capacitive load the clock drives. At any given drive
strength, the rise/fall time becomes slower as the output load
increases. As an example, for a 3.3V SiT8008 device with
default drive strength setting, the typical rise/fall time is 1ns for
15 pF output load. The typical rise/fall time slows down to
2.6ns when the output load increases to 45 pF. One can
Drive strength code is inserted here. Default setting is “-”
[i=s] This post was last edited by Yunhu Congbai on 2022-2-10 10:40 [/i] ## Preface GD32L233 supports hardware random numbers, awesome +1. Let's first talk about the concept of random numbers. True ra...
[i=s]This post was last edited by qwqwqw2088 on 2020-7-21 22:37[/i]The LM5036 is a highly integrated half-bridge PWM controller with integrated auxiliary bias power supply, providing a high power dens...
Hello everyone in July~ I am Guan Guan who wants to do something~ Guan Guan I have always wanted to do something in the RF sector, but I don’t have any good ideas. I have been thinking and procrastina...
[table=98%] [tr][td][align=right][align=left][size=15px][size=4]The good gift goddess will not run away and light up my heart[/size][/size][/align][align=left] [/align][align=left][align=left]Original...
24 GHz to 44 GHz Wideband Integrated Upconverter and Downconverter Boosts Microwave Radio Performance While Reducing SizeAnalog Devices has introduced a pair of highly integrated microwave up-down con...
According to Tencent's Deep Net, Yu Chengdong recently stated at an internal presentation for the consumer business that Huawei will continue to make mobile phones and will return as a king in 2023. ...[Details]
According to German media reports, as smartphones become increasingly powerful and people become more dependent on them, Volkswagen plans to develop a set of "Mirror-Link" technologies to simplify...[Details]
1. Hardware Platform:
Zhengdian Atom i.MX6U Alpha Development Board
2. SDK Package Introduction
NXP has officially written an SDK package for I.MX6ULL. In the SDK package, ...[Details]
Today, He Gang, President of Huawei's terminal mobile phone product line, announced that the shipment volume of Huawei Enjoy 9 Plus in China has exceeded 10,000,000 units, or 10 million units. The fu...[Details]
Recently, NavInfo passed the highest level 3 assessment of TISAX (Trusted Information Security Assessment Exchange), further enhancing its ability to provide products and services to upstream and dow...[Details]
More than a century ago, the Ford Model T became the first mass-produced automobile. While the Model T is no longer comparable to modern cars, its manufacturing concepts remain popular today, such as...[Details]
BYD stated on its interactive platform earlier this year that whoever masters advanced battery technology will master the future of electric vehicles. Under the wave of electrification, leading ca...[Details]
On September 10, 2024, the Ministry of Industry and Information Technology issued the "Guidelines for the Promotion and Application of the First Set of Major Technological Equipment (2024 Editi...[Details]
As a necessity of this era, mobile phones connect many people's lives, work and other aspects. However, as mobile phones can handle more and more things and their performance becomes more powerf...[Details]
Preface The 2021 Macroblock Technology Seminar was held online on December 8. Through cooperation with Dream Animation, XR shooting techniques were used to create a new type of seminar in the XR st...[Details]
This article will present a block diagram (SBD) of a HEV multi-cell battery pack using TI digital power controllers and multi-cell battery devices . Design Considerations Plug-in hybrid ele...[Details]
What if I change the parameter configuration? Then compile again to package errors As follows In fact, we are close to here. In the article "Transplanting s3c2440 ads program to keil (Part 2)"...[Details]
1 Introduction In power production and electrical testing, it is often necessary to measure power frequency voltage and frequency. There are many types of power frequency voltage meters and frequen...[Details]
In digital circuit testing, it is necessary to use several instruments and instruments to observe the test phenomena and results. Commonly used electronic measuring instruments include multimeters,...[Details]
Medical dialysis equipment is a kind of medical instrument widely used in clinical medical diagnosis and medical research. It is equivalent to the glomerular part of the kidney and is used to treat...[Details]