SL16010DC [SILICON]
Low Jitter and Power Clock Generator with SSCG;型号: | SL16010DC |
厂家: | SILICON |
描述: | Low Jitter and Power Clock Generator with SSCG |
文件: | 总8页 (文件大小:136K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
SL16010DC
Low Jitter and Power Clock Generator with SSCG
Key Features
Description
The SL16010DC is a low power dissipation spread
spectrum clock generator using SLI proprietary low jitter
•
Low power dissipation
- 13.5mA-typ CL=15pF
- 18.0mA-max CL=15pF
3.3V +/-10% power supply range
27.000MHz crystal or clock input
27.000MHz REFCLK
100MHz SSCLK with SSEL0/1 spread options
Low CCJ Jitter
PLL. The SL16010DC provides two output clocks.
REFCLK (Pin-9) which is a buffered output of the
27.000MHz input crystal and SSCLK (Pin-5) which is
synthesized as 100.000MHz nominal by an internal PLL
using the 27.00MHz external input crystal or clock.
•
•
•
•
•
•
•
•
•
•
•
In addition, SSEL0 (Pin-7) and SSEL1 (Pin-3) spread
percent selection control inputs enable users to select
from 0.0% (no spread) to -3.0% down spread at
100.000MHz SSCLK output to reduce and optimize
system EMI levels.
Low LT Jitter
Internal Voltage Regulators
45% to 55% Output Duty Cycle
On-chip Crystal Oscillator
-10 to +85 Temperature Range
10-pin 3x3x0.75 mm TDFN package
The SL16010DC operates in an extended temperature
range of -10 to +85°C.
Application
Contact SLI for other programmable frequencies, Spread
Spectrum Clock (SSC) options, as well as 2.5V+/-10 and
1.8V+/-5% power supply options.
•
•
•
•
•
•
Video Cards
NB and DT PCs
HDTV and DVD-R/W
Routers, Switches and Servers
Data Communications
Embeded Digital Applications
Benefits
•
•
•
•
EMI Reduction
Improved Jitter
Low Power Dissipation
Eleminates external Xtals or XOs
Block Diagram
REFCLK
27.000MHz
9
5
300K
Low Jitter PLL
With
Modulation Control
SSCLK
100.000MHz
XIN/CLKIN
XOUT
1
10
Input Decoder
4
6
8
2
7
3
VDD1 VSS1
VDD2 VSS2
SSEL0
SSEL1
Figure 1. Block Diagram
Rev 2.6, August 1, 2010
400 West Cesar Chavez, Austin, TX 78701
Page 1 of 8
www.silabs.com
1+(512) 416-8500
1+(512) 416-9669
SL16010DC
Pin Configuration
XOUT
REFCLK
VDD2
XIN/CLKIN
1
2
3
4
5
10
9
VSS2
8
SSEL1
VDD1
7
SSEL0
SSCLK
6
VSS1
Figure 2. 10-Pin TDFN (3x3x0.75 mm)
Table 1. Pin Description
Pin
Pin Name
Pin Type
Pin Description
Number
1
XIN/CLKIN
Input
External crystal or clock input. Capacitance at this pin is 4 pF-typ.
Power supply ground for 27.000MHz REFCLK output.
2
3
VSS2
Power
Input
SSEL1
SSEL1 spread percent selection pin. Refer to Table 5 for available
spread options using SSEL1 pin. Three state, Low (L), Middle (M) and
High (H) digital input logic levels. This pin has 150kΩ-typ input pull down
resistor.
4
5
VDD1
Power
Output
Positive power supply for 100.000MHz SSCLK output. 3.3V +/-10%.
SSCLK
SSCLK clock output. 100.000MHz nominal. Refer to Table 5 for available
spread % options by using SSEL0 and SSEL1 control pins.
6
7
VSS1
Power
Input
Power supply ground for 100.000MHz SSCLK output.
SSEL0
SSEL spread percent selection pin. Refer to Table 5 for available
spread options using SSEL0 pin. Three state, Low (L), Middle (M) and
High (H) digital input logic levels. This pin has 150kΩ-typ input pull down
resistor.
8
9
VDD2
REFCLK
XOUT
Power
Output
Output
Positive power supply for 27.000MHz REFCLK output. 3.3V +/-10%.
REFCLK clock output. 27.000MHz nominal.
10
Crystal output. Capacitance at this pin 4 pF-typ. If clock input is used,
leave this pin not connected (N/C).
Rev 2.6, August 1, 2010
Page 2 of 8
SL16010DC
Table 2. Absolute Maximum Ratings
Description
Supply voltage, VDD
Condition
Min
-0.5
-0.5
-10
Max
4.2
Unit
V
All Inputs and Outputs
VDD+0.5
85
V
Ambient Operating Temperature
Storage Temperature
In operation, extended C grade
No power is applied
°C
°C
°C
°C
V
-65
150
Junction Temperature
In operation, power is applied
-
125
Soldering Temperature
-
260
ESD Rating (Human Body Model)
ESD Rating (Charge Device Model)
ESD Rating (Machine Model)
JEDEC22-A114D
JEDEC22-C101C
JEDEC22-A115D
-4,000
-1,500
-200
4,000
1,500
200
V
V
Table 3. DC Electrical Characteristics (C-Grade)
Unless otherwise stated VDD= 3.3V+/- 10%, CL=15pF and Ambient Temperature range -10 to +85Deg C
Description
Operating Voltage
Input Low Voltage
Input Middle Voltage
Input High Voltage
Symbol
Condition
Min
2.97
Typ
Max
3.63
Unit
VDD1/2 VDD1=VDD2=3.3V +/-10%
3.3
V
V
VINL
VINM
VINH
SSEL0 and SSEL1
SSEL0 and SSEL1
SSEL0 and SSEL1
0
-
-
-
0.2
0.4VDD
0.9VDD
0.6VDD
VDD
V
V
CMOS Level, Pin-1
If input is clock
Input High Voltage
Input Low Voltage
VINH1
VINL1
0.7VDD
0
-
-
VDD
CMOS Level, Pin-1
If input is clock
0.3VDD
V
Output Low Voltage
Output High Voltage
VOL
VOH
IOL=15mA, Pins 5 and 9
IOH=-15mA , Pins 5 and 9
-
-
-
0.4
-
V
V
VDD-0.4
SSEL=1, M or 0, CL=15pF,
VDD=3.63V and T=85°C
Power Supply Current
IDD
-
13.5
18.0
mA
Input Capacitance
Input Capacitance
CIN1
CIN2
XIN and XOUT, Pins 1 and 10
SSEL0/1, Pins 7 and 3
-
-
4
3
-
pF
pF
5
SSCLK and REFCLK,
Pins 5 and 9
Load Capacitance
Pull Down Resistor
CL
-
-
15
pF
RPD
100
150
250
kΩ
Table 4. AC Electrical Characteristics (C-Grade)
Unless otherwise stated VDD= 3.3V+/-10%, CL=15pF and Ambient Temperature range -10 to +85 Deg C
Parameter
Symbol
Condition
Min
Typ
Max
Unit
Input crystal or clock range, +/-10 ppm
crystal accuracy if a crystal is used
Frequency Range
FR-1
-
27.000
-
MHz
Rev 2.6, August 1, 2010
Page 3 of 8
SL16010DC
Frequency Range
Frequency Range
Frequency Accuracy
Frequency Accuracy
FR-2
FR-3
REFCLK, Pin 9
SSCLK, Pin 5
-
27.000
100.000
+/-0
-
MHz
MHz
ppm
ppm
-
-
FACC1 REFCLK, Pin 9
-30
-30
30
30
FACC2 SSCLK, Pin 5, SSEL0/1=0
+/-0
REFCLK, Pin 9, CL=5pF, measured
from 20% to 80% of VDD
Rise and Fall Time
Rise and Fall Time
Rise and Fall Time
Rise and Fall Time
TR/F-1
TR/F-2
TR/F-3
TR/F-4
-
-
-
-
1.0
1.5
1.5
2.0
ns
ns
ns
ns
REFCLK, Pin 9, CL=15pF, measured
from 20% to 80% of VDD
SSCLK, Pin 5, CL=5pF, measured
from 20% to 80% of VDD
0.75
1.5
1.0
SSCLK, Pin 5, CL=15pF, measured
from 20% to 80% of VDD
1.75
SSCLK and REFCLK, Pins 5 and 9,
measured at VDD/2, CL=15pF
Output Duty Cycle
DC
45
50
55
%
Cycle-to-Cycle Jitter
Long Term Jitter
CCJ
LTJ
SSCLK/REFCLK, Pins 5 and 9
REFCLK, Pins 9, 10,000 cycles
-
-
125
130
200
300
ps
ps
Power-up Time
(VDD)
Time from 0.9VDD to valid frequency
at output Pins 5 and 9
tPU1
-
2.0
5.0
ms
Spread Percent
Change Settling Time
Time from SSEL0/1 change to stable
SSCLK with spread %
tSS%
MF
-
31
-
-
32
-
1.0
33
ms
kHz
Modulation Frequency
SSCLK, 100MHz nominal, Pin 5
Modulation Type and
Slew Rate
SSCLK, Pin 5, Triangular Modulation
Profile
FMTSR
0.125
%/μs
Table 5. SSEL1 and SSEL0 versus Spread % Selection at SSCLK
SSEL1 (Pin 3)
SSEL0 (Pin 7)
Spread Percent (%)
SSCLK (Pin 5)
Low (VSS)
Low (VSS)
Low (VSS)
Middle (VDD/2)
High (VDD)
Spread Off (No Spread)
-0.50%
-2.5%
-0.25%
-0.75%
-1.0%
-1.5%
-2.0%
-3.0%
Low (VSS)
Middle (VDD/2)
Middle (VDD/2)
Middle (VDD/2)
High (VDD)
Low (VSS)
Middle (VDD/2)
High (VDD)
Low (VSS)
High (VDD)
Middle (VDD/2)
High (VDD)
High (VDD)
Note: Middle (VDD/2) state requires 5kΩ/5kΩ external resistors as shown in Figure 3, page 5.
Rev 2.6, August 1, 2010
Page 4 of 8
SL16010DC
Table 6. Recommended Crystal Specifications
Description
Min
-
Typ
Max
-
Unit
MHz
Nominal Frequency (Fundamental
Crystal)
27.000
Crystal Accuracy
Load Capacitance
-
8
-
+/-10
-
ppm
pF
12
-
18
7.0
30
1.0
Shunt Capacitance
pF
Equivalent Series Resistance (ESR)
Drive Level
-
-
Ω
-
-
mW
VDD
VDD
3-Level Logic
LOW=VSS
3-Level Logic
HIGH=VDD
3-Level Logic
Middle=VDD/2
5KΩ
5KΩ
5KΩ
SSEL0
or
SSEL1
INPUT
SSEL0
or
SSEL1
INPUT
SSEL0
or
SSEL1
INPUT
7/3
7/3
7/3
5KΩ
VSS
VSS
HIGH (H) = VDD
MIDDLE (M) = VDD/2
LOW (L) = VSS
Figure 3. FSEL0 and FSEL1 Spread % Selection Logic
Note: SSEL0 and SSEL1 pins use 3-Level L(LOW) = VSS, M(MIDDLE)=VDD/2 and H(HIGH) = VDD
3-Level logic to provide 9 spread % values at SSCLK (pin 5) as given in Table 5.
Use 5kΩ/5kΩ external resistor divider at SSEL0 and SSEL1 pins from VDD to VSS to obtain VDD/2
for M=VDD/2 Logic level as shown above in Figure 3.
Rev 2.6, August 1, 2010
Page 5 of 8
SL16010DC
External Components and Design Considerations
Typical Application Circuit
VDD
10μF
0.1μF
0.1μF
VDD2(8)
VDD1(4)
CL1
XIN(1)
SSCLK(5)
100MHz
27MHz
REFCLK(9)
27MHz
XOUT(10)
VDD
CL2
SL16010DC
External crystal load
capacitors are required if
crystal is used.
5K
This example is
configured for -0.5%
Spread
SSEL0=M (VDD/2) and
SSEL1=LOW (VSS)
If external clock (XO) is
used leave Pin-10 XOUT
unconnected (N/C) and
drive Pin-1 XIN with clock.
SSEL0(7)
SSEL1(3)
5K
VSS1(6)
VSS2(2)
5K
Figure 4. Typical Application Schematic
Comments and Recommendations
Crystal and Crystal Load: Only use a parallel resonant fundamental AT cut crystal. DO NOT USE higher overtone
crystals. To meet the crystal initial accuracy specification (in ppm) make sure that external crystal load capacitor is
matched to crystal load specification. To determine the value of CL1 and CL2, use the following formula;
C1 = C2 = 2CL – (Cpin + Cp)
Where: CL is load capacitance stated by crystal manufacturer
Cpin is the SL16010 pin capacitance (4pF)
Cp is the parasitic capacitance of the PCB traces.
EXAMPLE; if a crystal with CL=12pF specification is used and Cp=1pF (parasitic PCB capacitance on PCB), 19 or
20pF external capacitors from pins XIN (pin-1) and XOUT (Pin-10) to VSS are required since CXIN=CXOUT=4pF for
the SL1610DC product. Users must verify Cp value.
Decoupling Capacitor: A decoupling capacitor of 0.1μF must be used between VDD1/2 pins and VSS1/2 pin. Place
the capacitor on the component side of the PCB as close to the VDD1/2 pins as possible. The PCB trace to the
VDD1/2 pins and to the VSS via should be kept as short as possible Do not use vias between the decoupling
capacitor and the VDD1/2 pins. In addition, a 10uf capacitor should be placed between VDD and VSS.
Series Termination Resistor: A series termination resistor is recommended if the distance between the outputs
(REFCLK and SSCLK) and the load if PCB trace is over 1 ½ inch. The nominal impedance of the outputs is about 24
Ω. Use 22 Ω resistors in series with the outputs to terminate 50Ω trace impedance and place 22 Ω resistors as close
to the clock outputs as possible.
Rev 2.6, August 1, 2010
Page 6 of 8
SL16010DC
Package Outline and Package Dimensions
10-Pin TDFN Package (3x3x0.75 mm)
Dimentions are in mm
2.00+/-0.10
0.75+/-0.05
0.50
10
6
1 0
.
0
-
+ /
C: 0.25X45°C
Pin #1 ID
0 0
.
3
0.30+/-0.05
5
1
0.00-0.05
0.25+/-0.05
3.00+/-0.10
Top View
Bottom View
Side View
0°
0.20+/-0.025
Side View
Table 7. Thermal Characteristics
Parameter
Symbol
θJA1
Condition
Min
Typ
75
Max
Unit
Still air
-
-
-
-
-
-
°C/W
°C/W
°C/W
Thermal Resistance
Junction to Ambient
θJA2
1m/s air flow
3m/s air flow
70
θJA3
55
Thermal Resistance
Junction to Case
θJC
Independent of air flow
-
25
-
°C/W
Rev 2.6, August 1, 2010
Page 7 of 8
SL16010DC
Table 8. Ordering Information
Ordering Number
Marking
Shipping Package
Package
Temperature
SL16010DC
SL16010DC
SL16010DC
Tube
10-pin TDFN
10-pin TDFN
-10 to 85°C
-10 to 85°C
SL16010DCT
Tape and Reel
Note:
1. SL16010DC is RoHS compliant and Halogen Free.
Product Revisions History
Revision
Rev 0.5
Rev 1.0
Date
Originator
C. Ozdalga
C. Ozdalga
Description
Original.
12/12/2009
1/30/2009
Reduce IDD-max to 18 mA from 28 mA. Change Cxin/Cxot from 4 pF to 6 pF.
Change R/R divider from 10Ω/10kΩ to 5kΩ/5kΩ. Add Pull-down resistors
definition for SSEL0/1 pins on Pin Description Table. Improve Typical Application
Circuit. Remove LTJ for SSCLK until new specification is obtained from
customer.
Rev 1.0
Rev 2.0
Rev 2.1
Rev 2.2
Rev 2.3
2/23/2009
2/30/2009
4/14/2009
4/22/2009
9/1/2009
C. Ozdalga
C. Ozdalga
C. Ozdalga
C. Ozdalga
C. Ozdalga
Change 13.5mA-max to 15mA-typ (Key Features – Page-1)
Final production version revision number change to Rev 2.0.
Correct Page 7 package pin number typing error.
Page 3 CIN1, CXI/CXOUT pin capacitance changed to 4pF-typ from 6pF-typ.
Replace “floating” with “VDD/2” in table 5 on page 4 and add note under the
same table 5 for clarification. Redo Figure 3 to clarify 3-Level Logic and add 5KΩ
resistor from SSEL1 to VSS in Figure 4 on page 6. Change Table 1 to Table 5
on pin description table page 2 for SSEL1 and SSEL0 rows.
Rev 2.4
Rev 2.5
9/3/2009
6/4/2010
C. Ozdalga
C. Ozdalga
Replace “floating” with “VDD/2” in table 5 on page 4 under SSEL1.
Add clock input specifications. SL16010DC can be driven by an external crystal
or clock.
Rev 2.6
8/1/2010
C. Ozdalga
Add Halogen Free, page 8.
The information in this document is believed to be accurate in all respects at the time of publication but is subject to change without
notice. Silicon Laboratories assumes no responsibility for errors and omissions, and disclaims responsibility for any consequences
resulting from the use of information included herein. Additionally, Silicon Laboratories assumes no responsibility for the functioning
of undescribed features or parameters. Silicon Laboratories reserves the right to make changes without further notice. Silicon
Laboratories makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor
does Silicon Laboratories assume any liability arising out of the application or use of any product or circuit, and specifically disclaims
any and all liability, including without limitation consequential or incidental damages. Silicon Laboratories products are not designed,
intended, or authorized for use in applications intended to support or sustain life, or for any other application in which the failure of
the Silicon Laboratories product could create a situation where personal injury or death may occur. Should Buyer purchase or use
Silicon Laboratories products for any such unintended or unauthorized application, Buyer shall indemnify and hold Silicon
Laboratories harmless against all claims and damages.
Rev 2.6, August 1, 2010
Page 8 of 8
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