ICS ICS527R-02IT

ICS527-02
Clock Slicer User Configurable PECL Input Zero Delay Buffer
Description
Features
The ICS527-02 Clock Slicer is the most flexible way to
generate a CMOS output clock from a PECL input
clock with zero skew. The user can easily configure the
device to produce nearly any output clock that is
multiplied or divided from the input clock. The part
supports non-integer multiplications and divisions. A
SYNC pulse indicates when the rising clock edges are
aligned with zero skew. Using Phase-Locked Loop
(PLL) techniques, the device accepts an input clock up
to 200 MHz and produces an output clock up to 160
MHz.
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The ICS527-02 aligns rising edges on PECLIN with
FBIN at a ratio determined by the reference and
feedback dividers.
For a PECL input and output clock with zero delay, use
the ICS527-04.
Packaged as 28-pin SSOP (150 mil body)
Synchronizes fractional clocks rising edges
PECL IN to CMOS OUT
Pin selectable dividers
Zero input to output skew
User determines the output frequency—no software
needed
Slices frequency or period
Input clock frequency of 1.5 MHz to 200 MHz
Output clock frequencies from 2.5 MHz to 160 MHz
Very low jitter
Duty cycle of 45/55
Operating voltage of 3.3 V
Advanced, low-power CMOS process
Industrial temperature version available
For a CMOS input and PECL output with zero delay,
use the ICS527-03.
Block Diagram
R6:R0
7
PECLIN
2
VDD
Reference
Divider
PECLIN
33 ohm
Phase Comparator,
Charge Pump, and
Loop Filter
FBIN
VCO
Feedback
Divider
2
GND
PDTS
Divide
by 2
1
0
33 ohm
CLK2
Feedback can
come from
CLK1 or CLK2
(not both)
DIV2
2
S1:S0
1
MDS 527-02 F
Integrated Circuit Systems, Inc.
Output
Divider
SYNC
7
F6:F0
●
CLK1
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ICS527-02
Clock Slicer User Configurable PECL Input Zero Delay Buffer
Pin Assignment
Output Frequency Range Table
R5
1
28
R4
R6
2
27
R3
D IV 2
3
26
R2
S0
4
25
R1
0
S1
5
24
R0
VDD
6
23
VDD
P E C L IN
7
22
P E C L IN
8
21
GND
S1 S0
Output Frequency (MHz)
Commercial
Industrial
0
10 - 50
16 - 45
0
1
5 - 40
8 - 33
C LK1
1
0
4 - 10
4-8
C LK2
1
1
20 -160
32 - 140
9
20
GND
O ECLK2
10
19
PDTS
F0
11
18
F B IN
F1
12
17
F6
F2
13
16
F5
OECLK2
DIV2
CLK2
F3
14
15
F4
0
X
Z
1
0
SYNC
1
1
CLK1/2
CLK2 Operation Table
28-pin 150 mil body SSOP
Pin Descriptions
Pin
Number
Pin
Name
Pin
Type
1,2, 24-28
R5, R6,
R0-R4
Input
Reference divider word input pins determined by user. Forms a binary number
from 0 to 127. Internal pull-up.
3
DIV2
Input
Selects CLK2 function to output a SYNC signal or a divide by 2 of CLK1 based
on the table above. Internal pull-up.
4, 5
S0, S1
Input
Select pins for output divider determined by user. See table above. Internal
pull-up.
6, 23
VDD
Power
Connect to +3.3 V.
7
PECLIN
Input
True PECL input clock.
8
PECLIN
Input
Complementary PECL input clock.
9, 20
GND
Power
Connect to ground
10
OECLK2
Input
CLK2 Output Enable. CLK2 tri-stated when low. Internal pull-up.
11-17
F0-F6
Input
Feedback divider word input pins determined by user. Forms a binary number
from 0 to 127. Internal pull-up
18
FBIN
Input
Feedback clock input
19
PDTS
Input
Power Down. Active low. Turns off entire chip when low, both clock outputs are
tri-stated. Internal pull-up.
21
CLK2
Output
Output clock 2. Can be SYNC pulse or a low skew divide by 2 of CLK1.
22
CLK1
Output
Output clock 1.
2
MDS 527-02 F
Integrated Circuit Systems, Inc.
Pin Description
●
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ICS527-02
Clock Slicer User Configurable PECL Input Zero Delay Buffer
External Components
P E C L IN
Decoupling Capacitors
As with any high performance mixed-signal IC, the
ICS527-02 must be isolated from system power supply
noise to perform optimally.
Decoupling capacitors of 0.01µF must be connected
between each VDD and the PCB ground plane. The
capacitor must be connected close to the device to
minimize lead inductance.
P E C L IN
C LK1
C LK2
p h a s e is
in d e t e r m in a te
C LK 1 F eedback
Series Termination Resistor
Clock output traces over one inch should use series
termination. To series terminate a 50Ω trace (a
commonly used trace impedance), place a 33Ω resistor
in series with the clock line, as close to the clock output
pin as possible. The nominal impedance of the clock
output is 20Ω.
P E C L IN
P E C L IN
C LK1
C LK2
C LK 2 Feedback
Using the ICS527-02 Clock Slicer
First use DIV2 to select the function of the CLK2
output. If DIV2 is high, a divide by 2, low skew version
of CLK1 is present on CLK2. If DIV2 is low, a SYNC
pulse is generated on CLK2. The SYNC pulse goes
high synchronously with the rising edges of PECLIN
and CLK1 that are de-skewed. The SYNC function
operates at CLK1 frequencies up to 66 MHz. If neither
CLK1/2 or a SYNC pulse are required, then CLK2
should be disabled by connecting OECLK2 to ground.
This will also give the lowest jitter on CLK1.
Next, the feedback scheme should be chosen. If CLK2
is being used as a SYNC pulse, or is tri-stated, then
CLK1 must be connected to FBIN. If CLK2 is selected
to be CLK1/2 (DIV2=1, OECLK2=1) then either CLK1
or CLK2 must be connected to FBIN. The choice
between CLK1 or CLK2 is illustrated by the following
examples where the device has been configured to
generate CLK1 that is twice the frequency on PECLIN.
Using CLK1 as feedback will always result in
synchronized rising edges between PECLIN and CLK1
if CLK1 is used as feedback. CLK2 could be a falling
edge compared to PECLIN. Therefore, wherever
possible it is recommended to use CLK2 for feedback,
which will synchronize the rising edges of all three
clocks.
More complicated feedback schemes can be used,
such as incorporating multiple output buffers in the
feedback path. An example is given later in the
datasheet. The fundamental property of the ICS527-02
is that it aligns rising edges on PECLIN and FBIN at a
ratio determined by the reference and feedback
dividers.
Set S1 and S0 (page 2) based on the output frequency.
Lastly, the divider settings should be selected. This is
described in the following section.
Determining ICS527-02 Divider Settings
The user has full control in setting the desired output
clock over the range shown in the table on page 2. The
user should connect the divider select input pins
directly to ground (or VDD, although this is not required
because of internal pull-ups) during Printed Circuit
Board layout, so the ICS527-02 automatically produces
3
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●
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ICS527-02
Clock Slicer User Configurable PECL Input Zero Delay Buffer
the correct clock when mounted on the board. It is also
possible to connect the inputs to parallel I/O ports in
order to switch frequencies.
S0 and S1 should be selected depending on the
frequency of CLK1. The table on page 2 gives the
ranges.
The output of the ICS527-02 can be determined by the
following simple equation:
The dividers are expressed as integers. For example, if
a 50 MHz output on CLK1 is desired from a 40 MHz
input, the reference divider word (RDW) should be 2
and the feedback divider word (FDW) should be 3
which gives the required 5/4 multiplication. If multiple
choices of dividers are available, then the lowest
numbers should be used. In this example, the output
divide (OD) should be selected to be 2. Then R6:R0 is
0000010, F6:F0 is 0000011 and S1:S0 is 00. Also, this
example assumes CLK1 is connected to FBIN.
FDW + 2
RDW + 2
FB Frequency = Input Frequency × -----------------------Where:
Reference Divider Word (RDW) = 0 to 127
Feedback Divider Word (FDW) = 0 to 127
FB Frequency is the same as either CLK1 or
CLK2 depending on feedback connection
Also, the following operating ranges should be
observed:
If you need assistance determining the optimum divider
settings, please send an e-mail to
[email protected] with the desired input clock and
the desired output frequency.
Input Frequency
300kHz < ------------------------------------------- < 20 MHz
RDW + 2
Typical Example
The layout diagram below will produce the waveforms shown on the right.
VDD
0.01µF
R5
R4
R6
R3
DIV2
R2
S0
R1
S1
R0
VDD
0.01µF
40 MHz
PECLIN
VDD
40 MHz
PECLIN
CLK1
40 MHz
PECLIN
CLK2
GND
GND
OECLK2
PDTS
F0
FBIN
F1
F6
F2
F5
F3
F4
33Ω
50 MHz
PECLIN
SYNC
33Ω
50 MHz
CLK1
SYNC
CLK2
Note: The series termination resistor is located before the feedback trace
4
MDS 527-02 F
Integrated Circuit Systems, Inc.
●
525 Race Street, San Jose, CA 95126
Revision 022806
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ICS527-02
Clock Slicer User Configurable PECL Input Zero Delay Buffer
Multiple Output Example
In this example, an input clock of 125 MHz is used. Eight copies of 50 MHz are required as are eight copies
of 25 MHz, de-skewed and aligned to the 125 MHz input clock. The following solution uses the
MK74CB217 which has dual 1 to 8 buffers with low pin-to-pin skew.
VDD
INA
INB
R6
R3
QA0
QB0
DIV2
R2
QA1
QB1
S0
R1
QA2
QB2
S1
R0
VDD
VDD
VDD
125 MHz
PECLIN
125 MHz
PECLIN
0.01µF
VDD
VDD
CLK1
50M
CLK2
25M
0.01µF
QA3
QA4
MK74CB217
R4
ICS527-02
0.01µF
R5
VDD
0.01µF
QB3
QB4
GND
GND
GND
GND
OECLK2
PDTS
GND
GND
F0
FBIN
QA5
QB5
F1
F6
QA6
QB6
F2
F5
QA7
QB7
F3
F4
OEA
OEB
The layout design above produces the waveforms shown below. Note: Series terminating resistors are not shown.
125 M H z,
PEC LIN
25 M H z,
Q A0-7
50 M H z,
Q B0-7
P EC LIN not show n
PCB Layout Recommendations
For optimum device performance and lowest output
phase noise, the following guidelines should be
observed.
1) Each 0.01µF decoupling capacitor should be
mounted on the component side of the board as close
to the VDD pin as possible. No via’s should be used
between decoupling capacitor and VDD pin. The PCB
trace to VDD pin should be kept as short as possible,
as should the PCB trace to the ground via.
3) An optimum layout is one with all components on the
same side of the board, minimizing vias through other
signal layers. Other signal traces should be routed
away from the ICS527-02. This includes signal traces
just underneath the device, or on layers adjacent to the
ground plane layer used by the device.
2) To minimize EMI the 33Ω series termination resistor,
if needed, should be placed close to the clock outputs.
5
MDS 527-02 F
Integrated Circuit Systems, Inc.
●
525 Race Street, San Jose, CA 95126
Revision 022806
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tel (408) 297-1201
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ICS527-02
Clock Slicer User Configurable PECL Input Zero Delay Buffer
Absolute Maximum Ratings
Stresses above the ratings listed below can cause permanent damage to the ICS527-02. These ratings,
which are standard values for ICS commercially rated parts, are stress ratings only. Functional operation of
the device at these or any other conditions above those indicated in the operational sections of the
specifications is not implied. Exposure to absolute maximum rating conditions for extended periods can
affect product reliability. Electrical parameters are guaranteed only over the recommended operating
temperature range.
Item
Rating
Supply Voltage, VDD
7V
All Inputs and Outputs
-0.5 V to VDD+0.5 V
Ambient Operating Temperature
-40 to +85°C
Storage Temperature
-65 to +150°C
Junction Temperature
125°C
Soldering Temperature
260°C
Recommended Operation Conditions
Parameter
Min.
Typ.
Max.
Units
Ambient Operating Temperature, ICS527R-02
0
–
+70
°C
Ambient Operating Temperature, ICS527R-02I
-40
–
+85
°C
+3.135
+3.3
+3.465
V
Power Supply Voltage (measured in respect to GND)
DC Electrical Characteristics
Unless stated otherwise, VDD = 3.3V ±5%, Ambient Temperature 0 to +70°C
Parameter
Symbol
Operating Voltage
VDD
Supply Current
IDD
Supply Current, Power Down
IDDPD
Input High Voltage
VIH
Input Low Voltage
VIL
Conditions
Min.
Typ.
Max.
Units
3.135
3.3
3.465
V
15 MHz in, 60 MHz
out, no load
18
mA
PDTS=0
20
µA
2
V
0.8
V
Input Voltage, peak-to-peak
PECLIN, PECLIN
0.3
1
V
Common Mode Range
PECLIN, PECLIN
VDD-1.4
VDD-0.6
V
Output High Voltage
VOH
IOH = -12 mA
Output Low Voltage
VOL
IOL = 12 mA
0.4
6
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ICS527-02
Clock Slicer User Configurable PECL Input Zero Delay Buffer
Parameter
Symbol
Conditions
Input Capacitance
CIN
Except PECLIN and
FBIN
Short Circuit Current
On-chip pull-up resistor
Min.
Typ.
Max.
Units
5
pF
IOS
±70
mA
RPU
270
kΩ
AC Electrical Characteristics
Unless stated otherwise, VDD = 3.3 V ±5%, Ambient Temperature -40 to +85° C
Parameter
Symbol
Input Frequency
Conditions
Min.
FIN
Output Frequency, CLK1
FOUT
0 to +70°C
-40 to +85°C
Typ.
Max.
Units
1.5
200
MHz
2.5
160
MHz
4
140
MHz
Output Rise Time
tOR
0.8 to 2.0 V, CL=15 pF
1
ns
Output Fall Time
tOF
2.0 to 0.8 V, CL=15 pF
1
ns
Output Duty Cycle (% high
time)
tOD
Measured at VDD/2,
CL=15 pF
55
%
Power Down Time, PDTS low to
clocks tri-stated
50
ns
Power Up Time, PDTS high to
clocks stable
10
ms
Absolute Clock Period Jitter
tja
One sigma Clock Period Jitter
tjs
Input to output skew
tIO
PECLIN to CLK1,
Note 1
Device to device skew
tpi
Common PECLIN,
measured at FBIN
45
Deviation from mean
50
± 90
ps
40
ps
-250
0
250
ps
500
ps
Note 1: Assumes clocks with same rise time, measured from rising edges at VDD/2.
7
MDS 527-02 F
Integrated Circuit Systems, Inc.
●
525 Race Street, San Jose, CA 95126
Revision 022806
●
tel (408) 297-1201
●
www.icst.com
ICS527-02
Clock Slicer User Configurable PECL Input Zero Delay Buffer
Package Outline and Package Dimensions (28-pin SSOP, .150 mil Body, 0.025 mm Pitch)
Package dimensions are kept current with JEDEC Publication No. 95, MO-153
Millimeters
28
Symbol
E1
E
INDEX
AREA
1 2
D
A
2
Min
A
A1
A2
b
C
D
E
E1
e
L
α
aaa
Inches
Max
Min
1.35
1.75
0.10
0.25
-1.50
0.20
0.30
0.18
0.25
9.80
10.00
5.80
6.20
3.80
4.00
0.635 Basic
0.40
1.27
0°
8°
-0.10
Max
.053
.069
.0040
.010
-.059
.008
.012
.007
.010
.386
.394
.228
.244
.150
.157
0.025 Basic
.016
.050
0°
8°
-0.004
A
A
1
c
-Ce
SEATING
PLANE
b
L
aaa C
Ordering Information
Part / Order Number
Marking
Shipping Packaging
Package
Temperature
ICS527R-02
ICS527R-02
Tubes
28-pin SSOP
0 to +70°C
ICS527R-02T
ICS527R-02
Tape and Reel
28-pin SSOP
0 to +70°C
ICS527R-02I
ICS527R-02I
Tubes
28-pin SSOP
-40 to +85°C
ICS527R-02IT
ICS527R-02I
Tape and Reel
28-pin SSOP
-40 to +85°C
While the information presented herein has been checked for both accuracy and reliability, Integrated Circuit Systems (ICS)
assumes no responsibility for either its use or for the infringement of any patents or other rights of third parties, which would
result from its use. No other circuits, patents, or licenses are implied. This product is intended for use in normal commercial
applications. Any other applications such as those requiring extended temperature range, high reliability, or other extraordinary
environmental requirements are not recommended without additional processing by ICS. ICS reserves the right to change any
circuitry or specifications without notice. ICS does not authorize or warrant any ICS product for use in life support devices or
critical medical instruments
8
MDS 527-02 F
Integrated Circuit Systems, Inc.
●
525 Race Street, San Jose, CA 95126
Revision 022806
●
tel (408) 297-1201
●
www.icst.com