ETC SL2309SC-1HT

SL2309
⎯
Low Jitter and Skew 10 to 140 MHz Zero Delay Buffer (ZDB)
Key Features
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Description
10 to 140 MHz operating frequency range
Low output clock skew: 50ps-typ
Low output clock jitter:
⎯ 50 ps-typ cycle-to-cycle jitter
Low part-to-part output skew: 150 ps-typ
3.3 V power supply range
Low power dissipation:
⎯ 28 mA-max at 66 MHz
⎯ 44 mA –max at 140 MHz
One input drives 9 outputs organized as 4+4+1
Select mode to bypass PLL or tri-state outputs
SpreadThru™ PLL that allows use of SSCG
Standard and High-Drive options
Available in 16-pin SOIC and TSSOP packages
Available in Commercial and Industrial grades
Applications
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Printers and MFPs
Digital Copiers
PCs and Work Stations
DTV
Routers, Switchers and Servers
Digital Embeded Systems
The SL2309 is a low skew, low jitter and low power Zero
Delay Buffer (ZDB) designed to produce up to nine (9)
clock outputs from one (1) reference input clock, for high
speed clock distribution applications.
The product has an on-chip PLL which locks to the input
clock at CLKIN and receives its feedback internally from
the CLKOUT pin.
The SL2309 has two (2) clock driver banks each with four
(4) clock outputs. These outputs are controlled by two (2)
select input pins S1 and S2. When only four (4) outputs
are needed, four (4) bank-B output clock buffers can be tristated to reduce power dissipation and jitter. The select
inputs can also be used to tri-state both banks A and B or
drive them directly from the input bypassing the PLL and
making the product behave like a Non-Zero Delay Buffer
(NZDB).
The high-drive (-1H) version operates up to 140MHz and
low drive (-1) version operates up to 100MHz at 3.3V.
Benefits
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Up to nine (9) distribution of input clock
Standard and High-Dirive levels to control impedance
level, frequency range and EMI
Low power dissipation, jitter and skew
Low cost
Block Diagram
Low Pow er and
Low Jitter
P LL
MUX
CLK OU T
C LKIN
CLK A1
CLK A2
C LKA3
CLKA4
S2
Input Selection
Decoding Logic
S1
CLKB1
C LKB2
C LKB3
2
2
C LKB4
VD D
Rev 1.1, May 29, 2007
GN D
Page 1 of 12
2200 Laurelwood Road, Santa Clara, CA 95054 Tel: (408) 855-0555 Fax: (408) 855-0550 www.SpectraLinear.com
SL2309
Pin Configuration
16-Pin SOIC and TSSOP
Pin Description
Pin
Number
Pin Name
Pin Type
Pin Description
1
CLKIN
Input
2
CLKA1
Output
Buffered Clock Output, Bank A. Weak pull-down (250kΩ).
3
CLKA2
Output
Buffered Clock Output, Bank A. Weak pull-down (250kΩ).
4
VDD
Power
3.3V Power Supply.
5
GND
Power
Power Ground.
6
CLKB1
Output
Buffered Clock Output, Bank B. Weak pull-down (250kΩ).
7
CLKB2
Output
Buffered Clock Output, Bank B. Weak pull-down (250kΩ).
8
S2
Input
Select Input, select pin S2. Weak pull-up (250kΩ).
9
S1
Input
Select Input, select pin S1. Weak pull-up (250kΩ).
10
CLKB3
Output
Buffered Clock Output, Bank B. Weak pull-down (250kΩ).
11
CLKB4
Output
Buffered Clock Output, Bank B. Weak pull-down (250kΩ).
12
GND
Power
Power Ground.
13
VDD
Power
3.3V Power Supply.
14
CLKA3
Output
Buffered Clock Output, Bank A. Weak pull-down (250kΩ).
15
CLKA4
Output
Buffered Clock Output, Bank A. Weak pull-down (250kΩ).
16
CLKOUT
Output
Buffered Clock Output, PLL Internal Feedback Output. Weak pull-down (250kΩ).
Rev 1.1, May 29, 2007
Reference Frequency Clock Input. Weak pull-down (250kΩ).
Page 2 of 12
SL2309
General Description
Select Input Control
The SL2309 is a low skew, low jitter Zero Delay Buffer with
very low operating current.
The SL2309 provides two (2) input select control pins
called S1 (Pin-9) and S2 (Pin-8). This feature enables
users to select various states of output clock banks-A and
bank-B, output source and PLL shutdown features as
shown in the Table 2.
The product includes an on-chip high performance PLL
that locks into the input reference clock and produces nine
(9) output clock drivers tracking the input reference clock
for systems requiring clock distribution.
in addition to CLKOUT that is used for internal PLL
feedback, there are two (2) banks with four (4) outputs in
each bank, bringing the number of total available output
clocks to nine (9).
Input and Output Frequency Range
The input and output frequency range is the same. But, it
depends on the drive and CL levels as given in the below
Table 1.
Drive
CL(pF)
Min(MHz)
Max(MHz)
HIGH
15
10
140
HIGH
30
10
100
LOW
15
10
100
LOW
30
10
66
Table 1. Input/Output Frequency Range
If the input clock is DC (GND to VDD) or floating, this is
detected by an input frequency detection circuitry and all
nine (9) clock outputs are forced to Hi-Z. The PLL is
shutdown to save power. In this shutdown state, the
product draws less than 12μA-max supply current.
In PLL by-pass mode (S2=1 and S1=0), the detection
circuit is disabled and input frequency range is 10 to
100MHz for standard (-1) drive and 10 to 140MHz for high
(-1H) drive.
SpreadThru™ Feature
If a Spread Spectrum Clock (SSC) were to be used as an
input clock, the SL2309 is designed to pass the
modulated Spread Spectrum Clock (SSC) signal from its
reference input to the output clocks. The same spread
characteristics at the input are passed through the PLL
and drivers without any degradation in spread percent
(%), spread profile and modulation frequency
Rev 1.1, May 29, 2007
The S1 (Pin-9) and S2 (Pin-8) inputs include 250 kΩ weak
pull-up resistors to VDD.
PLL Bypass Mode
If the S1 and S2 pins are logic Low(0) and High(1)
respectively, the on-chip PLL is shutdown and bypassed,
and all the nine output clocks bank A, bank B and
CLKOUT clocks are driven by directly from the reference
input clock. In this operation mode SL2309 works like a
non-ZDB fanout buffer. In this operation mode the input
power-down detection circuit is disabled and outputs
follow the input clock from DC to rated frequencies based
on drive levels and load specifications.
High and Low-Drive Product Options
The SL2309 is offered with High Drive “-1H” and Standard
Drive “-1” options. These drive options enable the users
to control load levels, frequency range and EMI. Refer to
the switching electrical tables for the details.
Skew and Zero Delay
All outputs should drive the similar load to achieve the
output-to-output skew and input-to-output specifications
given in the switching electrical tables. However, Zero
Delay between input and outputs can be adjusted by
changing the loading at CLKOUT relative to the banks A
and B clocks since CLKOUT is the feedback to the PLL.
Power Supply Range (VDD)
The SL2309 is designed to operate at VDD=3.3V (+/10%). An internal on-chip voltage regulator is used to
provide PLL constant power supply of 1.8V, leading to a
consistent and stable PLL electrical performance in terms
of skew, jitter and power dissipation.
Refer to SL23EP09 for 3.3V to 2.5V and SL23EPL09 for
1.8V power supply operations.
Page 3 of 12
SL2309
S2
S1
Clock A1-A4
Clock B1-4
CLKOUT
Output Source
PLL Status
0
0
Tri-state
Tri-state
Driven
PLL
On
0
1
Driven
Tri-state
Driven
PLL
On
1
0
Driven
Driven
Driven
Reference
Off
1
1
Driven
Driven
Driven
PLL
On
Table 2. Select Input Decoding
1500
1000
500
0
-30
-25
-20
-15
-10
-5
0
5
10
15
20
25
30
-500
-1000
-1500
Output Load Difference: FBK Load – CLKA or CLKB Load (pF)
Figure 1. CLKIN Input to CLK A and B Delay
(In terms of load difference between CLKOUT and CLK A and B)
Rev 1.1, May 29, 2007
Page 4 of 12
SL2309
Absolute Maximum Ratings
Description
Condition
Min
Max
Unit
Supply voltage, VDD
– 0.5
4.6
V
All Inputs and Outputs
– 0.5
VDD+0.5
V
Ambient Operating Temperature
In operation, C-Grade
0
85
°C
Ambient Operating Temperature
In operation, I-Grade
– 40
85
°C
Storage Temperature
No power is applied
– 65
150
°C
Junction Temperature
In operation, power is applied
–
125
°C
–
260
°C
2000
–
V
Min
Max
Unit
3.0
3.6
V
0
85
°C
– 40
85
°C
Soldering Temperature
ESD Rating (Human Body Model)
MIL-STD-883, Method 3015
Operating Conditions: Unless otherwise stated VDD=3.3V+/-10% and both C and I Grades
Symbol
Description
Condition
VDD
3.3V Supply Voltage
3.3V+/-10%
TA
Operating Temperature(Ambient) Commercial
Industrial
CLOAD
Load Capacitance
10 to 140 MHz, -1H high drive
All active PLL modes
10 to 100 MHz, -1H high drive
All active PLL modes
10 to 100MHz, -1 standard drive
All active PLL modes
10 to 66MHz, -1 standard drive
All active PLL modes
–
15
pF
–
30
pF
–
15
pF
–
30
pF
CIN
Input Capacitance
S1, S2 and CLKIN pins
tpu
Power-up Time
Power-up time for all VDDs to reach
minimum VDD voltage (VDD=3.0V).
CLBW
Closed-loop bandwidth
3.3V, (typical)
1.2
MHz
ZOUT
Output Impedance
3.3V, (typical), -1H high drive
22
Ω
3.3V, (typical), -1 standard drive
32
Ω
Rev 1.1, May 29, 2007
–
7
pF
0.05
100
ms
Page 5 of 12
SL2309
DC Electrical Specifications: Unless otherwise stated VDD=3.3V+/-10% and both C and I Grades
Symbol
Description
Condition
Min
Max
Unit
3.0
3.6
V
VDD
Supply Voltage
VIL
Input LOW Voltage
CLKIN, S2 and S1 Pins
–
0.8
V
VIH
Input HIGH Voltage
CLKIN, S2 and S1 pins
2.0
VDD+0.3
V
IIL
Input LOW Current
CLKIN, S2 and S1 Pins, 0 < VIN < 0.8V
–
25
µA
IIH
Input HIGH Current
CLKIN, S2 and S1 Pins, VIN = VDD
–
50
µA
VOL
Output LOW Voltage
(All outputs)
IOL = 8 mA (standard drive)
–
0.4
V
IOL = 12 mA (high drive)
–
0.4
V
VOH
Output HIGH Voltage
(All outputs)
IOH = –8 mA (standard drive)
2.4
–
V
IOH = –12 mA (high drive)
2.4
–
V
12
µA
25
µA
–
20
mA
–
28
mA
–
36
mA
–
44
mA
175
325
kΩ
IDDPD
IDD1
IDD2
IDD3
IDD4
RPU/D
Power Down Supply Current
C-Grade
CLKIN=0 to VDD or floating (input
will be pulled-down by 250kΩ
I-Grade
weak pull-down on-chip resistor)
All Outputs CL=0, 33MHz CLKIN
Power Supply Current
S2=S1=1 (High)
All Outputs CL=0, 66MHz CLKIN
Power Supply Current
S2=S1=1 (High)
All Outputs CL=0, 100MHz CLKIN
Power Supply Current
S2=S1=1 (High)
All Outputs CL=0, 140MHz CLKIN
Power Supply Current
S2=S1=1 (High)
Pins-1/2/3/6/7/8/9/10/11/14/15/16
Pull-up and Pull-down Resistors
250kΩ-typ
Rev 1.1, May 29, 2007
–
–
Page 6 of 12
SL2309
Switching Specifications: Unless otherwise stated VDD=3.3V+/-10% and both C and I Grades
Symbol
FMAX1
FMAX2
INDC
OUTDC
Description
Condition
Maximum Frequency
(Input=Output )
All Active PLL Modes
Maximum Frequency
(Input=Output )
PLL Bypass Mode
(S2=1 and S1=0)
[1]
[1]
Input Duty Cycle
[2]
Output Duty Cycle
[2]
tr/f
Rise, Fall Time (3.3V)
(Measured at: 0.8 to 2.0V)
[2]
Min
Typ
Max
High drive (-1H). All outputs CL=15pF
10
–
140
MHz
High drive (-1H), All outputs CL=30pF
10
–
100
MHz
Standard drive, (-1), All outputs CL=15pf
10
–
100
MHz
Standard drive, (-1), All outputs CL=30pf
10
–
66
MHz
High drive (-1H). All outputs CL=15pF
0
–
140
MHz
High drive (-1H), All outputs CL=30pF
0
–
100
MHz
Standard drive, (-1), All outputs CL=15pf
0
–
100
MHz
Standard drive, (-1), All outputs CL=30pf
0
–
66
MHz
Measured at 1.4V, Fout=66MHz, CL=15pF
30
50
70
%
Measured at 1.4V, Fout=66MHz, CL=15pF
40
50
60
%
High drive (-1H), CL=15pF
–
–
1.5
ns
High drive (-1H), CL=30pF
–
–
1.8
ns
Standard drive (-1), CL=15pF
–
–
2.2
ns
Standard drive (-1), CL=30pF
–
–
2.5
ns
All outputs CL=0 or equally loaded, -1 or
-1H drives
–
50
120
ps
–
150
400
ps
1.5
5
8.7
ns
–150
–
150
ps
Time from 90% of VDD to valid clocks on
all the output clocks
–
–
1.0
ms
Fin=Fout=66 MHz, <CL=15pF, -1H drive
–
50
100
ps
Fin=Fout=66 MHz, <CL=15pF, -1 drive
–
60
120
ps
Fin=Fout=66 MHz, <CL=30pF, -1H drive
–
65
130
ps
Fin=Fout=66 MHz, <CL=30pF, -1 drive
–
75
150
ps
t1
Output-to-Output Skew
(Measured at VDD/2)
t2
Device-to-Device Skew
(Measured at VDD/2)
All outputs CL=0 or equally loaded, -1 or
-1H drives
t3
Delay Time, CLKIN Rising
Edge to CLKOUT Rising
[2]
Edge
(Measured at VDD/2)
PLL Bypass mode
Only when S2=1 and S1=0
[2]
[2]
tPLOCK
PLL Lock Time
CCJ
Cycle-to-cycle Jitter
[2]
PLL enabled
All active PLL modes
Unit
Notes:
1. For the given maximum loading conditions. See CL in Operating Conditions Table.
2. Parameter is guaranteed by design and characterization. Not 100% tested in production.
Rev 1.1, May 29, 2007
Page 7 of 12
SL2309
External Components & Design Considerations
Typical Application Schematic
Comments and Recommendations
Decoupling Capacitor: A decoupling capacitor of 0.1μF must be used between VDD and VSS pins. Place the capacitor s
on the component side of the PCB as close to the VDD pins as possible. The PCB trace to the VDD pin and to the GND
via should be kept as short as possible. Do not use vias between the decoupling capacitor and the VDD pin.
Series Termination Resistor: A series termination resistor is recommended if the distance between the output clocks and
the load is over 1 ½ inch. The nominal impedance of the clock outputs is given on the page 4. Place the series termination
resistors as close to the clock outputs as possible.
Zero Delay and Skew Control: All outputs and CLKIN pins should be loaded with the same load to achieve “Zero Delay”
between the CLKIN and the outputs. The CLKOUT pin is connected to CLKIN internally on-chip for feedback to PLL, and
sees an additional 2 pF load with respect to Bank A and B clocks. For applications requiring zero input/output delay, the
load at the all output pins including the CLKOUT pin must be the same. If any delay adjustment is required, the
capacitance at the CLKOUT pin could be increased or decreased to increase or decrease the delay between Bank A and
B clocks and CLKIN.
For minimum pin-to-pin skew, the external load at all the Bank A and B clocks must be the same.
Rev 1.1, May 29, 2007
Page 8 of 12
SL2309
Switching Waveforms
Figure 2. Output to Output Skew
Figure 3. Input-to-Output Skew
Figure 4. Part-to-Part Skew
Rev 1.1, May 29, 2007
Page 9 of 12
SL2309
Package Drawing and Dimensions
16-Lead TSSOP (4.4mm)
9
16
6.250(0.246)
6.500(0.256)
4.300(0.169)
4.500(0.177)
Dimensions are in milimeters(inches).
Top line: (MIN) and Bottom line: (Max)
Pin-1 ID
1
8
2.900(0.114)
3.100(0.122)
1.100(0.043) MAX
0.650(0.025)
BSC
0.050(0.002)
0.150(0.006)
0.850(0.033)
0.950(0.037)
0.076(0.003)
0.190(0.007)
0.300(0.012)
0.650(0.025)
BSC
0.090(0.003)
0.200(0.008)
Gauge
Plane
Seating Plane
0 to 8°
0.500(0.020)
0.700(0.027)
Thermal Characteristics
Parameter
Thermal Resistance
Junction to Ambient
Thermal Resistance
Junction to Case
Rev 1.1, May 29, 2007
Symbol
Condition
Min
Typ
Max
Unit
θ JA
Still air
-
80
-
°C/W
θ JA
1m/s air flow
-
70
-
°C/W
θ JA
3m/s air flow
-
68
-
°C/W
θ JC
Independent of air flow
-
36
-
°C/W
Page 10 of 12
SL2309
Package Drawing and Dimensions (Cont.)
16-Lead SOIC (150 Mil)
16
9
Dimensions are in milimeters(inches).
Top line: (MIN) and Bottom line: (Max)
0.150(3.810)
0.157(3.987
Pin-1 ID
0.230(5.842)
0.244(6.197)
1
8
0.189(4.800)
0.196(4.978)
0.010(0.2540)
X 45°
0.016(0.406)
0.0075(0.190)
0.0098(0.249)
0.061(1.549)
0.068(1.727)
0.004(0.102)
0.050(1.270)
BSC
0.004(0.102)
0.0098(0.249)
Seating plane
0.016(0.406)
0.035(0.889)
0° to 8°
0.0138(0.350)
0.0192(0.487)
Thermal Characteristics
Parameter
Thermal Resistance
Junction to Ambient
Thermal Resistance
Junction to Case
Rev 1.1, May 29, 2007
Symbol
Condition
Min
Typ
Max
Unit
θ JA
Still air
-
120
-
°C/W
θ JA
1m/s air flow
-
115
-
°C/W
θ JA
3m/s air flow
-
105
-
°C/W
θ JC
Independent of air flow
-
60
-
°C/W
Page 11 of 12
SL2309
Ordering Information[3]
Ordering Number
Marking
Shipping Package
Package
Temperature
SL2309ZC-1
SL2309ZC-1
Tube
16-pin TSSOP
0 to 70°C
SL2309ZC-1T
SL2309ZC-1
Tape and Reel
16-pin TSSOP
0 to 70°C
SL2309ZC-1H
SL2309ZC-1H
Tube
16-pin TSSOP
0 to 70°C
SL2309ZC-1HT
SL2309ZC-1H
Tape and Reel
16-pin TSSOP
0 to 70°C
SL2309ZI-1
SL2309ZI-1
Tube
16-pin TSSOP
-40 to 85°C
SL2309ZI-1T
SL2309ZI-1
Tape and Reel
16-pin TSSOP
-40 to 85°C
SL2309ZI-1H
SL2309ZI-1H
Tube
16-pin TSSOP
-40 to 85°C
SL2309ZI-1HT
SL2309ZI-1H
Tape and Reel
16-pin TSSOP
-40 to 85°C
SL2309SC-1
SL2309SC-1
Tube
16-pin SOIC
0 to 70°C
SL2309SC-1T
SL2309SC-1
Tape and Reel
16-pin SOIC
0 to 70°C
SL2309SC-1H
SL2309SC-1H
Tube
16-pin SOIC
0 to 70°C
SL2309SC-1HT
SL2309SC-1H
Tape and Reel
16-pin SOIC
0 to 70°C
SL2309SI-1
SL2309SI-1
Tube
16-pin SOIC
-40 to 85°C
SL2309SI-1T
SL2309SI-1
Tape and Reel
16-pin SOIC
-40 to 85°C
SL2309SI-1H
SL2309SI-1H
Tube
16-pin SOIC
-40 to 85°C
SL2309SI-1HT
SL2309SI-1H
Tape and Reel
16-pin SOIC
-40 to 85°C
Notes:
3. The SL2309 products are RoHS compliant.
While SLI has reviewed all information herein for accuracy and reliability, Spectra Linear Inc. assumes no responsibility for the use of any
circuitry or for the infringement of any patents or other rights of third parties which would result from each use. This product is intended for
use in normal commercial applications and is not warranted not is it intended for use in life support, critical medical instruments, or any other
application requiring extended temperature range, high reliability, or any other extraordinary environmental requirements unless pursuant to
additional processing by Spectra Linear Inc., and an expressed written agreement by Spectra Linear Inc. Spectra Linear Inc. reserves the
right to change any circuitry or specification without notice.
Rev 1.1, May 29, 2007
Page 12 of 12