SEMTECH ACS8947T

ACS8947T JAM PLL
Jitter Attenuating, Multiplying Phase-Locked Loop with
Automatic Input Switch and Data Resynchronization Path
COMMUNICATIONS
ADVANCED COMMS
& SENSING
Introduction
FINAL
Features
The ACS8947T JAM PLL is a general pupose, Integer N,
jitter-attenuating, differential phase-locked loop for
generating low jitter output clocks. Frequency translation,
reference switching between clock inputs and
resynchronization features are provided also. Typical
application areas include Ethernet, SONET/SDH, PCI, 3G
and wireless systems.
Typical output jitter generation in a SONET/SDH OC-12
system is 2.8 ps RMS, making the ACS8947T an ideal
dejittering solution for use with Semtech clock and line
card parts ACS8510, ACS8520, ACS8525, ACS8522,
ACS8530 and ACS9510.
The ACS8947T has two differential frequencyprogrammable LVPECL reference inputs and one
differential synchronization input. The device is capable of
locking across a wide input frequency range of 580 kHz to
180 MHz. Four independently-supplied differential
outputs are available, programmable as LVPECL or CML.
Each output supports a maximum output frequency rate
of up to 625 MHz. All device settings are fully hardwire
configured. An external microprocessor is not required to
program the PLL.
Block Diagram
DATASHEET
Z
Highly configurable high performance Integer N PLL
with integrated VCO.
Z
VCO frequency range 2.35 GHz to 2.9 GHz.
Z
Configurable closed loop bandwidth from 2 kHz
upwards.
Z
PLL fully configured by hardwired configuration matrix:
no requirement for an external microprocessor.
Z
Full control over internal dividers allows the device to
be configured for a wide range of frequency
translation and jitter cleaning applications.
Z
Meets RMS jitter requirements for OC3 and OC12
telecommunications systems.
Z
Wide input frequency range of 580 kHz to 180 MHz.
Z
Wide output frequency range of 1.23 MHz to
625 MHz.
Z
Input activity monitors and lock detector.
Z
Automatic or manual control of reference selection.
Z
External feedback option.
Z
Wide tracking range of 200 ppm.
Z
Powerful evaluation board and GUI tool for
configuration and device assessment.
Z
3.3 V operation: temperature range - 40°C to +85°C.
Z
Small outline, leadless, 7 mm x 7 mm QFN48
package.
Figure 1 Simplified Block Diagram of the ACS8947T JAM PLL
Revision 1.00/September 2007© Semtech Corp.
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Table of Contents
FINAL
DATASHEET
Section
Page
Introduction ................................................................................................................................................................................................1
Block Diagram............................................................................................................................................................................................ 1
Features .....................................................................................................................................................................................................1
Pin Diagram ...............................................................................................................................................................................................3
Pin Descriptions .........................................................................................................................................................................................4
Description .................................................................................................................................................................................................8
Inputs .................................................................................................................................................................................................9
Clock Inputs ..............................................................................................................................................................................9
External feedback ................................................................................................................................................................. 10
Source Switching ................................................................................................................................................................... 10
Activity Alarms ....................................................................................................................................................................... 10
SYNC Input ............................................................................................................................................................................. 10
Input Divider DIVIP ................................................................................................................................................................. 10
Feedback Divider DIVFB ........................................................................................................................................................ 10
Odd Divider DIVODD ............................................................................................................................................................... 10
Phase and Frequency Detector ............................................................................................................................................. 11
Charge Pumps and External Low-Pass Filter........................................................................................................................ 11
Voltage Controlled Oscillator ................................................................................................................................................ 11
Output Multiplexer and Divider ............................................................................................................................................ 11
Outputs ........................................................................................................................................................................................... 11
Lock Detector ................................................................................................................................................................................. 12
Jitter Filtering .................................................................................................................................................................................. 12
Input Jitter Tolerance ..................................................................................................................................................................... 12
Jitter Transfer ................................................................................................................................................................................. 12
Phase Noise Performance ............................................................................................................................................................. 13
PLL Configuration ........................................................................................................................................................................... 13
Output Jitter .................................................................................................................................................................................... 14
Device Reset .................................................................................................................................................................................. 14
Layout Recommendations ............................................................................................................................................................ 14
Example Schematic ....................................................................................................................................................................... 15
Electrical Specifications ......................................................................................................................................................................... 16
Maximum Ratings .......................................................................................................................................................................... 16
Operating Conditions ..................................................................................................................................................................... 17
AC Characteristics ................................................................................................................................................................. 18
DC Characteristics ................................................................................................................................................................. 19
Input and Output Interface Terminations ..................................................................................................................................... 20
Jitter Performance ......................................................................................................................................................................... 23
Input/Output Timing ...................................................................................................................................................................... 25
Package Information .............................................................................................................................................................................. 26
Thermal Conditions ........................................................................................................................................................................ 27
References and Related Standards ...................................................................................................................................................... 28
Abbreviations .......................................................................................................................................................................................... 28
Trademark Acknowledgements ............................................................................................................................................................. 29
Revision Status/History ......................................................................................................................................................................... 29
Ordering Information .............................................................................................................................................................................. 30
Contact Information ................................................................................................................................................................................ 30
Revision 1.00/September 2007© Semtech Corp.
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Pin Diagram
FINAL
DATASHEET
Page 3
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Figure 2 ACS8947T Pin Diagram
Revision 1.00/September 2007© Semtech Corp.
ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Pin Descriptions
FINAL
In the I/O column of the pin description tables that follow:
DATASHEET
In the Type column:
I = input
O = output
I/O = bi-directional
P = power
A = analog
LVTTL/LVCMOSU = LVTTL/LVCMOS input with pull-up
resistor
LVTTL/LVCMOSD = LVTTL/LVCMOS input with pull
down resistor
Table 1 Power pins
Pin No.
Symbol
I/O
Type
Description
1, 4,
7, 10
VDDO1, VDDO2,
VDDO3, VDDO4
P
-
Independent voltage supplies to power each clock output (differential pair of pins)
OUT1N/P to OUT4N/P respectively. +3.3 V (±5%).
To disable an output and save power, tie associated VDD to 0V.
26
VDDADIV
P
-
Supply voltage for internal dividers in VCO loop, kept as an isolated supply to allow for low
supply noise for the output divider stages. +3.3 V (±5%).
29
VDDP1
P
-
Supply voltage to differential inputs, alarm and configuration pins. +3.3 V (±5%).
43
VDDP2
P
-
Supply voltage to SYNC input and output pins, rate selection pins, input selection pins
and reset pin. +3.3 V (±5%).
34
VDDARF
P
-
Supply voltage for phase and frequency detector (PFD), kept as an isolated supply to
allow for low supply noise. +3.3 V (±5%).
38
VDDOSC
P
-
Supply voltage to the internal VCO. +3.3 V (+5%/-10%).
39
VSSOSC
P
-
Supply ground 0 V for the internal VCO.
49
VSS0
P
-
Common supply ground 0 V.
This is the central leadframe pad on the underside of the package.
Table 2 Internally connected pins
Pin No.
37
Symbol
IC1
I/O
Type
Description
-
-
I/O
Type
Description
Connect to ground.
Table 3 Functional Pins
Pin No.
Symbol
2
OUT1N
O
CML or
LVPECL
One of four CML or LVPECL differential outputs, partnered with pin 3. Programmable at
spot frequencies from 1.23 MHz to 625 MHz. The output frequency is defined by the
configuration pin settings at power up or when RESETB is asserted (logic 0).
See PLL Configuration.
The output is ON when VDD01 is supplied with 3.3 V, or OFF when VDD01 is tied to zero
volts. If VDD01 is connected to 0 V, remove the external biasing resistors.
3
OUT1P
O
CML or
LVPECL
CML or LVPECL differential output partnered with pin 2. See pin 2 description for more
detail.
Revision 1.00/September 2007© Semtech Corp.
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
DATASHEET
Table 3 Functional Pins (cont...)
Pin No.
Symbol
I/O
Type
Description
5
OUT2N
O
CML or
LVPECL
One of four CML or LVPECL differential outputs, partnered with pin 6. Programmable at
spot frequencies from 1.23 MHz up to 625 MHz. The output frequency is defined by the
configuration pin settings at power up or when RESETB is asserted (logic 0).
See PLL Configuration.
The output is ON when VDD02 is supplied with 3.3 V, or OFF when VDD02 is tied to zero
volts. If VDD02 is connected to 0 V, remove the external biasing resistors.
6
OUT2P
O
CML or
LVPECL
CML or LVPECL differential output partnered with pin 5. See OUT2_N (pin 5) for more
detail.
8
OUT3N
O
CML or
LVPECL
One of four CML or LVPECL differential outputs, partnered with pin 9. Programmable at
spot frequencies from 1.23 MHz up to 625 MHz. The output frequency is defined by the
configuration pin settings at power up or when RESETB is asserted (logic 0).
See PLL Configuration.
The output is ON when VDD03 is supplied with 3.3 V, or OFF when VDD03 is tied to zero
volts. If VDD03 is connected to 0 V, remove the external biasing resistors.
9
OUT3P
O
CML or
LVPECL
CML or LVPECL differential output partnered with pin 8. See pin 8 description for more
detail.
11
OUT4N
O
CML or
LVPECL
One of four CML or LVPECL differential outputs, partnered with pin 12. Programmable at
spot frequencies from 1.23 MHz up to 625 MHz. The output frequency is defined by the
configuration pin settings at power up or when RESETB is asserted (logic 0).
See PLL Configuration.
The output is ON when VDD04 is supplied with 3.3 V, or OFF when VDD04 is tied to zero
volts. If VDD04 is connected to 0 V, remove the external biasing resistors.
12
OUT4P
O
CML or
LVPECL
CML or LVPECL differential output partnered with pin 11. See pin 11 description for more
detail.
13
ALARM1_CO0
O
LVTTL/
LVCMOS
Activity alarm output for the CLK1P/CLK1N input reference clock. Active high; high
indicating clock failure. It is also used to configure the device at power-up, where it is
used as a configuration output pin, that may be connected to CFG_IN[11:0] input pins as
required. See PLL Configuration.
14
ALARM2_CO1
O
LVTTL/
LVCMOS
Activity alarm output for the CLK2P/CLK2N input reference clock. Active high; high
indicating clock failure. It is also used to configure the device at power-up time, where it
is used as a configuration output pin, that may be connected to CFG_IN[11:0] input pins
as required. See PLL Configuration.
15
CFG_OUT2
O
LVTTL/
LVCMOS
Configuration pin, used in the configuration on power-up of expected input clock
frequency and Resync selection, by connecting to appropriate pin from the CFG_IN[11:0]
pins as required. See PLL Configuration.
16
ALARMC_CO3
O
LVTTL/
LVCMOS
Activity alarm output for the currently selected input reference clock. Active high; high
indicating clock failure. It is also used to configure the device at power-up, where it is
used as a configuration output pin that may be connected to CFG_IN[11:0] input pins as
required. See PLL Configuration.
17
LOCKB
O
Analog
Revision 1.00/September 2007© Semtech Corp.
Lock detect output. This is a pulse-width modulated output current, with each pulse
typically +10 μA. The output produces a pulse with a width in proportion to the phase
error seen at the internal phase detector. This pin should be connected via an external
parallel capacitor and resistor to ground. The pin voltage will then give an indication of
phase lock: When low, the device is phase locked; when high the device has frequent
large phase errors and so is not phase locked. The value of the RC components used
determines the time and level of consistency required for lock indication. If LOCKB is
disabled by configuration the LOCKB output is held low.
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
DATASHEET
Table 3 Functional Pins (cont...)
Pin No.
Symbol
I/O
Type
Description
18
CFG_IN0
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
19
CFG_IN1
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
20
CFG_IN2
I
LVTTL/
LVCMOSD
Schmitt
Trigger
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
21
CFG_IN3
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
22
CFG_IN4
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
23
CFG_IN5
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
24
CFG_IN6
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
25
CFG_IN7
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
27
CLK1N
I
LVPECL
Negative differential input reference clock partnered with pin 28. Accepts a wide range of
input frequencies from 580 kHz to 180 MHz. Accepts LVPECL, LVDS or CML inputs given
suitable external interface components (see Input and Output Interface Terminations).
Selection between CLK1 and CLK2 is configurable between manual or automatic. See
Table 5.
28
CLK1P
I
LVPECL
Positive differential input reference clock partnered with pin 27. Accepts a wide range of
input frequencies from 580 kHz to 180 MHz. Accepts LVPECL, LVDS or CML inputs given
suitable external interface components (see Input and Output Interface Terminations).
Selection between CLK1 and CLK2 is configurable between manual or automatic. See
Table 5.
30
CLK2N
I
LVPECL
Negative differential input reference clock partnered with pin 31. Accepts a wide range of
input frequencies from 580 kHz to 180 MHz. Accepts LVPECL, LVDS or CML inputs given
suitable external interface components (see Input and Output Interface Terminations).
Selection between CLK1 and CLK2 is configurable between manual or automatic. See
Table 5.
31
CLK2P
I
LVPECL
Positive differential input reference clock partnered with pin 30. Accepts a wide range of
input frequencies from 580 kHz to 180 MHz. Accepts LVPECL, LVDS or CML inputs given
suitable external interface components (see Input and Output Interface Terminations).
Selection between CLK1 and CLK2 is configurable between manual or automatic. See
Table 5.
32
SEL_CLK2
I
LVTTL/
LVCMOSD
Used in combination with AUTO_SEL (pin 33) to select the CLK1 input (low) or CLK2 input
(high) in manual control mode, or to select automatic switching mode as described in
Table 5.
33
AUTO_SEL
I
LVTTL/
LVCMOSD
Used in combination with SEL_CLK2 (pin 32) to select automatic switching mode as
described in Table 5.
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
DATASHEET
Table 3 Functional Pins (cont...)
Pin No.
Symbol
I/O
Type
Description
35
VCP
A
Analog
Connection for external loop filter components. This is the differential control voltage
input to the internal VCO and the internal differential charge pump output up to a level of
210 μA.
36
VCN
A
Analog
Connection for external loop filter components. This is the differential control voltage
input to the internal VCO and the internal differential charge pump output up to a level of
210 μA.
40
RESETB
I
LVTTL/
LVCMOSU
Schmitt
Trigger
Active low reset signal with pull up and Schmitt type input. Used to apply an active-low
Power-on Reset (POR) signal during system initialization. Should be connected via a
capacitor to ground or, if reset control by a microcontroller is required, via a 3.3 V control
line.
41
SYNCP
I
LVPECL
Differential input (typically 8 kHz) where the SYNC signal on this input is sampled and
resynchronized to the rising edge of the OUT1 clock signal. Paired with pin 42 (SYNCN).
Maximum input frequency is 40 MHz. Will accept LVDS, CML or LVPECL signals when
suitable external biasing components are used. See Input and Output Interface
Terminations.
42
SYNCN
I
LVPECL
Differential input (typically 8 kHz) where the SYNC signal on this input is sampled and
resynchronized to the rising edge of the OUT1 clock signal. Paired with pin 41 (SYNCP).
Maximum input frequency is 40 MHz. Will accept LVDS, CML or LVPECL signals when
suitable external biasing components are used. See Input and Output Interface
Terminations.
44
SYNC_OUT
O
LVTTL/
LVCMOS
A sampled and resynchronized version of the SYNC signal present on SYNCP (pin 41) and
SYNCN (pin 42). The SYNC_OUT signal is synchronized to the rising edge of the output
clock present on OUT1. If the SYNC function is used, the output frequency on OUT1
should be at least double the frequency of the SYNCP/SYNCN input and restricted to a
maximum of 80 MHz. This restriction affects the OUT1 signal only.
45
CFG_IN10
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
46
CFG_IN11
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
47
CFG_IN8
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
48
CFG_IN9
I
LVTTL/
LVCMOSD
Configuration input pin. Connection to this pin is defined by the ACS8947T evaluation
software GUI. See PLL Configuration.
Revision 1.00/September 2007© Semtech Corp.
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Description
FINAL
The ACS8947T is a highly configurable general purpose
Integer-N, low-jitter integrated PLL for signal cleaning,
dejittering and frequency translation. The PLL is built
around an integrated voltage controlled oscillator(VCO)
and can be used in a wide range of applications including
OC12 clock cleaning for SONET, SDH, Ethernet, PCI,
RapidIO, 3G and wireless systems.
DATASHEET
The device can be fully programmed, without the need for
a microprocessor, by hardwiring the configuration input
pins CFG_IN[11:0] to ALARM1_CO0, ALARM2_CO1,
CFG_OUT2, ALARMC_CO3, VDD and GND as defined by
the ACS8947T evaluation software GUI.
The PLL has a fully differential external loop filter, allowing
the closed loop bandwidth and damping factor to be
customized according to target system requirements. The
tables below show typical loop filter component values
and divider settings for various applications.
Table 4 Typical Loop Filter Component Values and Divider Settings
OSC/8
DIVIP
DIVODD
Closed
Damping
Loop
Factor
Bandwidth
(kHz)
Application
I/P
(MHz)
O/P
(MHz)
VCO
(MHz/
V)
PFD
(MHz)
E1
2.048
65.536
2883
2.048
176
1
11
2
DS1
1.544
49.408
2767
1.544
224
1
7
E3
34.368
68.736
2749
34.37
10
1
DS3
44.736
44.736
2863
44.74
8
SONET
19.44
622.08
2488
19.44
Ethernet
25
625
2500
Ethernet
62.5
125
Ethernet
10
PCI
ICP
(μA)
CP
(nF)
Cs
(μF)
Rs
(Ω)
3.8
210
1.5
22
470
2
3.8
210
1.2
15
680
5
10
1.2
160
0.56
0.068
2700
1
1
2
1.2
40
82
6.8
82
16
1
1
2
1.2
160
150
15
56
12.5
25
2
1
2
1.2
210
120
15
68
2500
62.5
5
1
5
2
1.2
40
82
15
82
100
2800
10
35
1
7
100
3.8
210
0.56
0.68
2700
133
133
2660
66.5
5
2
5
2
1.2
40
120
15
68
Memory
167
167
2672
167
2
1
1
2
3.8
10
4.7
68
150
3G
3.84
61.44
2457
3.84
80
1
5
30
1.7
210
0.18
0.68
1500
Wireless
153.6
153.6
2457
153.6
2
1
1
2
3.8
10
3.9
47
150
Revision 1.00/September 2007© Semtech Corp.
Divided By
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
The ACS8947T is available in a small form factor QFN48
package of outer dimensions 7 mm x 7 mm x 0.9 mm.
Figure 3 Example of EVB GUI
DATASHEET
An evaluation board and GUI software for calculating the
required loop filter component values and configuration
wiring connections, and for hands-on device assessment,
are available on request.
Inputs
See PLL Configuration for details on how to configure the
PLL dividers.
Clock Inputs
Either clock input can be manually or automatically
selected as the current reference, based on the detection
of clock activity. Signals AUTO_SEL and SEL_CLK2 shown
in Table 5 are used to control the input clock selection. In
automatic mode, the selection between CLK1 and CLK2
is non-revertive: i.e. if the PLL is locked on to CLK1 and
CLK1 fails and the PLL switches to CLK2, when CLK1
becomes operational again, the PLL does not revert to
CLK1.
The ACS8947T has two LVPECL differential clock inputs
(CLK1N/P and CLK2N/P) and is capable of locking across
a wide frequency range of 580 kHz to 180 MHz. If both
input clocks are being used, the frequency difference
between the signals presented to CLK1N/P and CLK2N/P
must be within ±100 ppm. Unused positive differential
inputs should be wired to GND and unused negative
differential inputs should be wired to VDD.
The clock inputs are designed to accept LVDS, LVPECLor
CML inputs, given suitable passive resistive and
capacitive interface components.
Table 5 Clock Input Selection Decoding
AUTO_SEL
SEL_CLK2
Selected Reference
Feedback Clock
0
0
CLK1
Internal path
0
1
CLK2
Internal path
1
0
CLK1
CLK2
1
1
AUTOMATIC SELECTION
(determined by
activity monitor)
Internal path
On device reset, the configuration protocol presets the
internal divider ratios and enables a fast frequency tuning
algorithm that temporarily forces PLL bandwidth and
locking range to be wide. This enables the PLL to
automatically scan and lock to the target reference
frequency present on the selected input channel.Once
lock is acquired, the PLL bandwidth is reduced and
frequency tracking range limited to ±200 ppm. It is
therefore important to ensure that the correct input
frequency is present on CLK1N/P and CLK2N/P prior to
resetting the ACS8947T.
Revision 1.00/September 2007© Semtech Corp.
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
External feedback
An external feedback mode is available and can be used
for greater control of phase discrepancies: for example
when using external buffers. In external feedback mode,
the reference clock is presented to CLK1N/P and the
external feedback signal is presented to CLK2N/P. In this
mode, CLK1N/P is the only permitted input.
Source Switching
Figure 4 Simplified State Diagram of Source Switching
ALARMC_CO3 = 1
ALARM1_CO0 = 0
CLK 1
ALARMC_CO3 = 1
ALARM2_CO1 = 0
ALARMC_CO3 is an additional activity alarm that monitors
clock inputs to the PFD. This signal is more sensitive than
ALARM1_CO0 and ALARM2_CO1, triggering after three
missing clock edges to the PFD rather than at complete
failure of the input reference clock. Although alarm
ALARMC_CO3 has greater sensitivity than the input
activity monitor, it may take longer to assert if the input
divide ratio is greater than 2.
All activity monitor flags are low during normal operation
and active high when missing clock cycles are detected.
SYNC Input
CLK 2
ALARM SIGNALS:
ALARMC_CO3 -- Activity alarm for the currently selected clock (from PFD)
ALARM1_CO0 -- Activity alarm for CLK1
ALARM2_CO1 -- Activity alarm for CLK2
F8946D_012SimpStateDiag_01
Figure 4 shows a simplified view of the automatic
switching behavior in the presence of activity alarms.
Signal ALARMC_CO3 from the PFD is used to disqualify a
clock, and signals ALARM1_CO0 and ALARM2_CO1
(representing no activity on input clocks CLK1 and CLK2
respectively), determine whether to select the remaining
clock. Switching between CLK1 and CLK2 is nonrevertive.
With ALARMC_CO3 providing a view of the currently
selected clock that is independent of the ALARM1_CO0
and ALARM2_CO1 signals, source selection behavior can
be more complex when these alarm signals disagree.
Consequently, to accommodate such behavior, the state
machine is necessarily more complex than that shown
here: e.g. when a clock signal is disconnected for a very
short period, or when an input clock is running at the
wrong frequency.
For more information, please contact Semtech Sales
Support.
In addition to the main input clock inputs, a single
differential SYNC input is provided. It provides a
resynchronization path to SYNC_OUT that is clocked and
synchronized to the rising edge of the OUT1 clock. The
SYNC input frequency should be limited to half the OUT1
clock rate, up to a maximum of 40 MHz. For correct
operation, the OUT1 output frequency should be at least
double that of the SYNC clock.
Input Divider DIVIP
The selected input clock is connected to the PFD via an
8-bit programable divider capable of division ratios from
1 to a maximum 256.
Feedback Divider DIVFB
The feedback path from the internal 2.35 GHz to 2.9 GHz
oscillator to the PFD includes a 9-bit programmable
divider that is capable of division ratios from 1 to a
maximum of 512. Depending on the chosen output
frequency, this divider is in series with a fixed divide-by-8
or the odd divider path described below.
Odd Divider DIVODD
Activity Alarms
Input activity monitors ALARM1_CO0 and ALARM2_CO1
flag the occurrence of six or more consecutive missing
cycles from inputs CLK1N/P and CLK2N/P. The alarm
signals operate on the input reference clock prior to the
internal PFD, and use an internal feedback clock from the
VCO to determine whether the reference clock has failed.
Revision 1.00/September 2007© Semtech Corp.
DATASHEET
The odd divider is capable of division ratios 1, 3, 5, 7,
9,11, 13 and 15. The output of the divider is connected to
the output multiplexing and divider stage. If odd number
division is used, the frequency adjustment factor applies
to all outputs - adjusting all selected output frequencies
proportionally.
Under some PLL configurations, the odd divider may also
be included in the feedback path to the PFD.
Page 10
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
Phase and Frequency Detector
The internal phase and frequency detector is designed to
operate across the full input frequency range of 580 kHz
to 180 MHz and includes the ALARMC_CO3 activity alarm.
Charge Pumps and External Low-Pass Filter
A differential charge pump is used to drive the external
loop filter via pins VCN and VCP. For linear operation of
the PLL, the differential voltage range is limited to ±1.2 V
centered around a typical common mode voltage of
1.25 V.
To maintain sensible external component values, the
magnitude of the charge pump current (IC) is dependent
on the OSC/8 divider ratio as defined in Table 6.
Table 6 Relationship of IC and OSC/8 Divider Ratio
DATASHEET
Refer to PLL Configuration for details on how to calculate
the loop filter component values for a given closed loop
bandwidth and phase margin. Automatic calculation is
available in the the ACS8947T evaluation software GUI.
Voltage Controlled Oscillator
The internal VCO operates across a frequency range of
2.35 GHz to 2.9 GHz. The VCO frequency is divided down
to the selected output rate, giving a precise 50/50
balanced mark/space ratio for the output.
Output Multiplexer and Divider
A 5-bit tapped, differential CML divider tree is used in
conjunction with the odd divider to generate the required
output frequencies. The divider ratios are set according to
the frequency list defined by the external configuration
wiring and cannot be modified once the device is locked.
The device automatically allocates the frequency list to
outputs as part of the PLL configuration sequence.
IC (μA)
OSC/8 Divide By
10
1 -> 2
Outputs
40
3 -> 8
160
9 -> 24
210
25 -> 512
Four programmable LVPECL/CML differential outputs are
provided via signal pairs OUT[4:1]N/P (pins 11/12, 8/9,
5/6 and 2/3). Interfacing to LVDS is also possible using
suitable passive components (see Input and Output
Interface Terminations). The frequency assigned to each
output is programable between 1.23 MHz and 625 MHz
and, during device reset, is set by the frequency map
defined by the configuration sequence. Although the
theoretical maximum output frequency of the PLL is
725 MHz, the output ports are only guaranteed to meet
VOH/VOL to a maximum of 625 MHz.
The closed loop PLL bandwidth is set by two identical sets
of passive RC components that connect to the differential
charge pump outputs pins VCN and VCP. Figure 5 shows
the recommended configuration of the second order loop
differential filter.
Figure 5 Configuration of Second Order Loop Filter
Revision 1.00/September 2007© Semtech Corp.
Each differential output has a dedicated power supply pin
that should be connected to VDD if the output is required
to be active. If an output port is not required, connect the
dedicated power pin to ground to disable the differential
output.
Page 11
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Lock Detector
FINAL
Input Jitter Tolerance
A simple lock detector is incorporated. It combines the
plus and minus phase errors output from the PFD so that,
if any phase error signal is present, the LOCKB output
drives a PWM +10 μA current. The mark/space ratio
indicates the current input phase error.
By filtering this signal with a basic external RC parallel
filter as shown in Figure 6, a signal whose output level
indicates PLL phase and frequency lock is obtained.
DATASHEET
Jitter tolerance is defined as the maximum amplitude of
sinusoidal jitter that can exist on the input reference clock
above which the device fails to acquire/maintain lock.
For the stand-alone device, the jitter tolerance for an
undivided reference (i.e. full rate PFD) is shown in
Figure 7.
For frequencies below the PLL bandwidth, jitter tolerance
is seen to decrease at a rate of -20 dB per decade. For
jitter frequencies above the PLL bandwidth, jitter
tolerance is limited to 0.9 UI p-p.
Figure 6 Lock Detector External RC Filter
Note...If the reference clock is divided, then the jitter tolerance
will be improved.
When the ACS8947T follows an ACS8525, the input jitter
tolerance is wholly defined by the latter. The system jitter
tolerance is dramatically increased due to the extended
phase capture range of the digital PLL within the
ACS8525.
Figure 7 Jitter Tolerance ACS8947T
Input Jitter Tolerance With 2kHz PLL Bandwidth
1000
Jitter Filtering
Input jitter is attenuated by the PLL with the frequency cutoff point (Fc), at which jitter is tracked or attenuated,
defined by the -3 dB point: i.e. the position of the first pole
of the PLL loop filter. The bandwidth is the frequency at
which the first pole occurs and is defined by the
component value selected for the filter.
100
Input Jitter Amplitude p-p (U I)
The filtering components are external so that the time to
indicate lock can be optimized for the application. The
output indicates both phase and frequency lock. During
off-frequency conditions, the LOCKB output is
predominately high.
ACS8947 Jitter
ACS8946
Tolerance
10
OC_12
Tolerance Mask
OC_48
Tolerance Mask
1
10
100
1000
10000
100000
1000000
0.1
0.01
Jitter Frequency Offset from Carrier (Hz)
For a 19.44 MHz input, using a loop filter bandwidth of
2 kHz and damping factor of 1.2 gives:
Z
Jitter Transfer
High input jitter attenuation and roll off:
- 20 dB/decade from first loop filter pole, (Fc);
- 40 dB/decade from 2nd pole (typically 10 x Fc).
Jitter peaking is less than 1 dB (dependent on the
loop filter components);
Z Typical final output jitter: e.g. 2.8 ps RMS measured
over the integration range of 12 kHz to 20 MHz offset
from carrier.
Z
Revision 1.00/September 2007© Semtech Corp.
Jitter transfer is a ratio of input jitter present on the
reference clock to filtered jitter present on the output
clock. The ACS8947T jitter transfer characteristic is
defined solely by the loop filter bandwidth.
Figure 8 is an example showing the measured jitter
transfer characteristic on a 19.44 MHz reference clock
with a closed loop bandwidth of 2 KHz and a damping
factor of 1.2.
Page 12
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Figure 8 Jitter Transfer Characteristic - ACS8947T
Stand-alone
FINAL
PLL Configuration
On device reset all divider ratios, charge pump settings,
lock detector mode and output pad types are set by the
Configuration Block, which decodes the wiring
connections present on CFG[11:0]. This allows the PLL to
be entirely configured without the need for an external
microprocessor.
ACS8944 RMS Jitter Transfer Curve
3.0
0.0
-3.0
-6.0
TBIL
H(s) dB
-9.0
The configuration pins CFG[11:0] (device pins 18:25 and
48:45) are hardwired (via VDD, GND, ALARM1_CO0,
ALARM2_CO1, CFG_OUT2, or ALARMC_CO3) to produce a
unique programming code. On device reset, this code is
decoded and used to configure the PLL.
-12.0
-15.0
-18.0
-21.0
-24.0
-27.0
100
DATASHEET
1000
10000
100000
Frequency (Hz)
Phase Noise Performance
The inherent jitter generation by the ACS8947T is shown
in the phase noise plot in Figure 9, measured on a
155.52 MHz output clock using an input reference of
19.44 MHz.
Evaluation software that calculates the configuration
hardwire connection matrix for CFG[11:0] based on the
required PLL setup is available for download from
Semtech. Figure 10 shows a typical connection sheet.
Figure 10 Example of ACS8947T Connection Sheet
Figure 9 Phase Noise Offset from Carrier of ACS8947T
622.08 MHz output clock
Typical Phase Noise @ 155.52MHz
1.0E+02
1.0E+03
1.0E+04
1.0E+05
Frequency (Hz)
1.0E+06
1.0E+07
0
(dBc/Hz)
-40
Phase Noise
-20
-80
-60
TBIL
-100
-120
Use of the ACS8947T evaluation software is the simplest
and preferred method of calculating the required divider
ratios as this will also calculate loop filter component
values and configuration wiring settings.
-140
-160
Revision 1.00/September 2007© Semtech Corp.
Page 13
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
DATASHEET
Figure 11 ACS8947T - Typical Closed Loop Transfer Function
Closed Loop
Gain GPO
Frequency
FPO
Output Jitter
Layout Recommendations
The output jitter meets all requirements of ITU, Telcordia
and ETSI standards for SONET rates up to 622.08 MHz
(OC-12/STM-4). See Electrical Specifications for details
on the jitter figures across the different output jitter
frequency bands relevant to each specification.
It is highly recommended that a stable and filtered 3.3 V
power supply is used for the ACS8947T. A separate
filtered power and ground plane is recommended, with
supply decoupling capacitors of 10 nF and 100 pF
utilizing good, high-frequency chip capacitors (0402 or
0603 format surface mount package) on each VDD.
Device Reset
The RESETB pin is active low and requires a minimum
reset pulse duration of 100 ms once the power supplies
are stable and powered up. When the reset process is
triggered, the required PLL settings are decoded from the
configuration wiring connections, and the internal control
logic waits for the presence of an input signal of
approximately the correct frequency.
When a suitable input clock signal is detected, the
ACS8947T calibrates the VCO using a fast tuning
algorithm, and both frequency-lock and phase-lock to the
input reference. This calibration routine is run only after a
reset condition, so the RESETB pin should be held low
until the input frequency is within 200 ppm of nominal.
Revision 1.00/September 2007© Semtech Corp.
For optimum jitter cleaning performance, additional care
should be taken over the supply connection to VDDOSC,
which should be supplied directly from a 3.3 V LDO or a
4R7/68UF low-pass filter.
The wiring connections required for device configuration
are calcuated by the ACS8947T Evaluation Software GUI.
This program provides a schematic definition for the wired
connections to CFG[11:0] and includes a loop filter
component calculator.
Good differential signal layout on the input and output
lines should be used to ensure matched track impedance
and phase. Contact Semtech directly for further layout
recommendations.
Page 14
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Example Schematic
FINAL
DATASHEET
Figure 12 Generic Line Card Clock Source with Protection - Example Schematic
Notes: (i) For configuration wiring information, refer to the ACS8947T evaluation software GUI.
(ii) For optimal performance, use a low voltage dropout (LDO) regulator to supply VDDA2.
Revision 1.00/September 2007© Semtech Corp.
Page 15
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Electrical Specifications
FINAL
DATASHEET
Maximum Ratings
Important Note. The absolute maximum ratings given in
Table 7 are stress ratings only, and functional operation
of the device at conditions other than those indicated in
Table 8 to Table 16 of this specification are not implied.
Exposure to the absolute maximum ratings for an
extended period may reduce the reliability or useful
lifetime of the product.
Table 7 Absolute Maximum Ratings
Parameter
Symbol
Minimum
Maximum
Units
Supply voltage (D.C.): VDD01, VDD02, VDD03,
VDD04, VDDP1, VDDP2, VDDADIV, VDDARF, VDDOSC
VDD
-0.5
3.6
V
Input voltage (non-supply pins):
Digital Inputs: CFG_IN0, CFG_IN1, CFG_IN2,
CFG_IN3, CFG_IN4, CFG_IN5, CFG_IN6, CFG_IN7,
CFG_IN8, CFG_IN9, CFG_IN10, CFG_IN11, SELCLK2,
AUTO_SEL, RESETB
VIN
-0.5
5.5
V
Input voltage (non-supply pins)
LVPECL Inputs: CLK1N, CLK1P, CLK2N, CLK2P,
SYNCN, SYNCP
ANALOG I/O: VCN, VCP, LOCKB
VIN
-0.5
VDD + 0.5
V
Output voltage (non-supply pins):
Digital Output: ALARM1_C01, ALARM2_CO1,
CFG_OUT2, ALARMC_CO3, SYNC_OUT
LVPECL Outputs: OUT1N, OUT1P, to OUT 4N/P
VOUT
-0.5
VDD + 0.5
V
TA
-40
+85
°C
Storage temperature
TSTOR
-50
+150
°C
Reflow temperature (Pb)
TREPB
-
+245
°C
TREPBFREE
-
+260
°C
ESDHBM
2
-
kV
ILU
±100
-
mA
Ambient operating temperature range
Reflow temperature (Pb Free)
ESD HBM (Human Body Model)(i), (ii)
Latchup(iii)
Notes: (i) All pins pass 2 kV HBM except VCN/VCP which are rated at 500 V HBM.
(ii) Tested to JEDEC standard JESD22-A114.
(iii) Tested to JEDEC standard JESD78.
Revision 1.00/September 2007© Semtech Corp.
Page 16
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Operating Conditions
FINAL
DATASHEET
Table 8 Operating Conditions
Parameter
Symbol
Minimum
Typical
Maximum
Units
VDD
3.135
3.3
3.465
V
VDDOSC
3.0
3.3
3.465
V
VDD
3.135
or
0 V*
3.3
3.465
V
TA
-40
-
+85
°C
VDD01 supply current
IDD01
-
29
33
mA
VDD02 supply current
IDD02
29
33
mA
VDD03 supply current
IDD03
29
33
mA
VDD04 supply current
IDD04
29
33
mA
VDDP1 supply current
IDDP1
25
31
mA
VDDP2 supply current
IDDP2
22
30
mA
VDDADIV supply current
IDDADIV
100
111
mA
VDDARF supply current
IDDARF
64
72
mA
VDDOSC supply current
IDDVOSC
20
25
mA
Supply voltage (DC): VDDP1, VDDP2, VDDADIV,
VDDARF,
Supply voltage (DC): VDDOSC
Supply voltage (DC): VDD01, VDD02, VDD03,
VDD04.
* 3.135. V min required to enable output. Supply
may be connected to 0 V to disable the associated
output.
Ambient temperature range
Device total power dissipation with all outputs on
@625 MHz. Excluding power dissipation in external
biasing components.
PTOT
-
1,1
1,2
W
Symbol
Minimum
Typical
Maximum
Units
Thermal resistance junction to ambient
θJA
-
-
25
°C/W
Operating junction temperature
TJCT
-
-
125
°C
Note...Supply currents for VDDOn assumes CML 50Ω
termination.
Thermal Characteristics
Table 9 Thermal Conditions
Parameter
Revision 1.00/September 2007© Semtech Corp.
Page 17
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
DATASHEET
AC Characteristics
Table 10 AC Characteristics
Parameter
Symbol
Minimum
Typical
Maximum
Units
Output to output skew(i)
tOSK
-
-
100
ps
Input to output delay
tPDIO
0.5
-
3.0
ns
SYNC_OUT to OUT1 delay
tPDSO
-2.9
-
-0.4
ns
OUT1 to SYNC set-up
tSS
3.7
-
-
ns
OUT1 to SYNC hold
tSH
2.8
-
-
ns
Input clock rise/fall time(ii) (CLK1, CLK2, SYNC)
tCRF
-
-
10
ns
tPECLRF
-
0.8
1.2
ns
tCMLRF
-
0.7
1.2
ns
SYNC_OUT rise/fall time(ii), (v)
tSRF
-
3.0
5.0
ns
Input clock duty cycle (CLK1, CLK2, SYNC)
tCDF
40
50
60
%
Output clock duty cycle
tODC
48
50
52
%
RESETB pulse width after power-up
tRPW
100
-
-
ms
Settling time before start of frequency tuning after
RESETB high
tFT
10
-
60
ms
Input reference frequency
FIN
0.580
-
180
MHz
FOUT
1.230
625
MHz
LVPECL output rise/fall time(ii), (iii)
CML output rise/fall
time(ii), (iv)
Output frequency
Notes: (i) Outputs running at same frequency.
(ii) Rise/fall time measured 10% to 90%.
(iii) Using output load specified in Figure 16.
(iv) Using output load specified in Figure 13.
(v) Using 50 Ω load.
(vi) Using 5 pF capacitive load.
Revision 1.00/September 2007© Semtech Corp.
Page 18
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
DATASHEET
DC Characteristics
Across all operating conditions, unless otherwise stated.
Table 11 VCN/VCP Differential Charge Pump Input/Output Port
Parameter
Symbol
Minimum
Typical
Maximum
Units
VCM
1.0
1.25
1.5
V
VTUNE
-
±1.2
-
V
Low level output voltage
VOL
GND + 0.2
-
-
V
High level output voltage
VOH
-
-
VDD - 0.2
V
Output current (10 μA)
IO
8
10
12
μA
Output current (40 μA)
IO
32
40
48
μA
Output current (160 μA)
IO
128
160
192
μA
Output current (210 μA)
IO
168
210
252
μA
Common mode voltage
VCN/VCP linear tuning range
Table 12 DC Characteristics: LVCMOS Input Ports with Internal Pull-down/LVCMOS Schmitt Input Port with Internal
Pull-up
Parameter
Symbol
Minimum
Typical
Maximum
Units
VIN High
VIH
2
-
-
V
VIN Low
VIL
-
-
0.8
V
Pull-down resistor
RPD
43
-
108
kΩ
Pull-up resistor (Schmitt Input)
RPU
53
-
113
kΩ
Input current
IIN
-10
-
+10
μA
Symbol
Minimum
Typical
Maximum
Units
LVPECL input offset voltage
differential inputs (Note (ii))
VIO_LVPECL
VDD-2.0
-
VDD-0.5
V
Input differential voltage
VID_LVPECL
0.1
-
1.4
V
LVPECL input low voltage
single-ended input (Note (i))
VIL_LVPECL_S
VSS
-
VDD-1.5
V
LVPECL input high voltage
single-ended input (Note (i))
VIL_LVPECL_S
VDD-1.3
-
VDD
V
Input high current
input differential voltage VID = 1.4 V
IIH_LVPECL
-10
-
+10
μA
Input low current
input differential voltage VID = 1.4 V
IIL_LVPECL
-10
-
+10
μA
Table 13 DC Characteristics: LVPECL Input Port
Parameter
Notes: (i) Unused differential input terminated to VDD-1.4 V.
(ii) Both pins must remain within the supply voltage, i.e. >VSS and <VDD.
Revision 1.00/September 2007© Semtech Corp.
Page 19
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
DATASHEET
Table 14 DC Characteristics: CML Output Port
Parameter
Symbol
Minimum
Typical
Maximum
Units
IOUT current source
IOUT
13.3
16
19.2
mA
Single-ended output voltage amplitude with 50 Ω
load to VDD and 50 Ω input impedance into next
stage.
VOS
-
400
-
mV
Differential output voltage amplitude with 50 Ω load
to VDD and 50 Ω input impedance into next stage on
both pins.
VOD
-
800
-
mV
Symbol
Minimum
Typical
Maximum
Units
LVPECL output low voltage (Note (i))
VOL_LVPECL
VDD-2.1
-
VDD-1.62
V
LVPECL output high voltage (Note (i))
VOH_LVPECL
VDD-1.45
-
VDD-0.88
V
LVPECL output differential voltage (Note (i))
VOD_LVPECL
0.37
-
1.22
V
Symbol
Minimum
Typical
Maximum
Units
Output low voltage @ IOL (MAX)
VOL
-
-
0.4
V
Output high voltage @ IOH (MIN)
VOH
2.4
-
-
V
Low level output current @ VOL = 0.4 V
IOL
2
-
-
mA
High level output current @ VOH = 2.4 V
IOH
2
-
-
mA
Table 15 DC Characteristics: LVPECL Output Port
Parameter
Note:
(i) With a 50 ohms load on each pin to VDD -2V
Table 16 DC Characteristics: LVTTL/CMOS Output Port
Parameter
Input and Output Interface Terminations
Interfacing to either the same type or electrically different
interface types is illustrated by the following circuit
diagrams in Figure 13 to Figure 18.
In applications where the output clocks are always
running, they may be AC coupled, allowing the receive end
to be at any common mode voltage, however, the lines
must always be terminated at their characteristic
impedance.
The preferred termination for the CML type output is 50 Ω
to VDD, as shown in Figure 13. AC coupling may be used
subsequently to translate the levels to other interface
types, e.g. to LVPECL/LVDS as shown in Figure 14.
Revision 1.00/September 2007© Semtech Corp.
The example of Figure 16 shows LVPECL to LVPECL
terminations with DC coupling, so that the ACS8947T
sees an equivalent load of around 50 Ω from the resistor
arrangement at the receiver end. Note that signal levels
given in the accompanying graph are nominal levels at
622.08 MHz, and will change with load.
The preferred termination circuitry for the LVDS signals
between the ACS8525/26/27 and the ACS8947T
LVPECL is shown in Figure 18. The bias for the LVPECL
input is set for AC inputs at a mid point of approximately
2 V (with VDD of 3.3 V), as opposed to a normal DC
coupled bias of VDD - 2 V. This is due to the push-pull
nature of an AC coupled signal.
Page 20
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
Where inputs to the ACS8947T are AC coupled, problems
may be experienced with activity detection. This is due to
noise/cross-talk on the inputs being interpreted as
activity. To avoid this, DC couple wherever possible and, if
AC coupling must be used, consider offsetting the DC bias
of the N and P signals. See Figure 15.
DATASHEET
Figure 15 Generic CML Output AC Coupled to LVPECL
Receiver
Figure 13 CML Output - DC Coupled to CML Receiver
130/120R mismatch is used in the input bias network in
Figure 15 to emulate a simplified differential Schmitt
trigger, reducing the susceptibility to input noise when no
input is connected.
Figure 14 JAM PLL CML Output DC coupled to LVPECL or
LVDS Receiver
Revision 1.00/September 2007© Semtech Corp.
Figure 16 LVPECL Output - DC Coupled to LVPECL or LVDS
Receiver
Page 21
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
DATASHEET
Figure 17 SETS LVDS Output - DC Coupled to LVPECL Receiver
SETS
LVDS
Output
OUTN
OUTP
JAM PLL
LVPECL
INPUT
Transmission
Line Impedance
50 Ohms
CLKN
CLKP
100R
F8946D_018LVDS2LVPECL_02
Figure 18 Generic LVDS - AC Coupled to LVPECL Receiver
VDD
LVDS
Output
Device
2K7
JAM PLL
2K7
LVPECL
INPUT
220nF
CLKN
OUTN
OUTP
Transmission
Line Impedance
50 Ohms
CLKP
100R
220nF
4K3
4K3
GND
F8946D_019LVDS2LVPECL_02
Note...Activity monitors will not function with this scheme as
noise may cause activity detection by mistake. Consider
replacing one 4K3 resistor with a 4k7 resistor.
Revision 1.00/September 2007© Semtech Corp.
Page 22
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Jitter Performance
FINAL
DATASHEET
Table 17 Phase Noise Parameters with LVPECL Input of 167 MHz and LVPECL Output of 167 MHz
Parameter
Symbol
Minimum
Typical
Maximum
Unit
Phase noise at 100 Hz
phn100
-
-64
-
dBc/Hz
Phase noise at 1 kHz
phn1k
-
-75
-
dBc/Hz
Phase noise at 10 kHz
phn10k
-
-91
-
dBc/Hz
Phase noise at 100 kHz
phn100k
-
-120
-
dBc/Hz
Phase noise at 1 MHz
phn1M
-
-142
-
dBc/Hz
Phase noise at 10 MHz
phn10M
-
-142
-
dBc/Hz
Phase noise at 20 MHz
phn20M
-
-142
-
dBc/Hz
JRMS
-
5.1
-
ps
Tj
-
138
-
ps
RMS jitter integrated from 12 kHz to 20 MHz
Total jitter
Notes: (i) Phase noise specifications when fin = 10 MHz and fout = 100 MHz.
(ii) PLL closed loop bandwidth set to 2 kHz with a damping factor of 3.8.
(iii) Total jitter is broadband jitter accumulated over 100 s.
Table 18 Phase Noise Parameters with LVPECL Input of 25 MHz and LVPECL Output of 625 MHz
Parameter
Symbol
Minimum
Typical
Maximum
Unit
Phase noise at 100 Hz
phn100
-
-60
-
dBc/Hz
Phase noise at 1 kHz
phn1k
-
-68
-
dBc/Hz
Phase noise at 10 kHz
phn10k
-
-79
-
dBc/Hz
Phase noise at 100 kHz
phn100k
-
-110
-
dBc/Hz
Phase noise at 1 MHz
phn1M
-
-135
-
dBc/Hz
Phase noise at 10 MHz
phn10M
-
-142
-
dBc/Hz
Phase noise at 20 MHz
phn20M
-
-142
-
dBc/Hz
JRMS
-
4.3
-
ps
Tj
-
198
-
ps
RMS jitter integrated from 12 kHz to 20 MHz
Total jitter
Notes: (i) Phase noise specifications when fin = 25 MHz and fout = 625 MHz.
(ii) PLL closed loop bandwidth set to 2 kHz with a damping factor of 1.2.
(iii) Total jitter is broadband jitter accumulated over 100 s.
Revision 1.00/September 2007© Semtech Corp.
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
DATASHEET
Table 19 Phase Noise Parameters with LVPECL Input of 62.5 MHz and LVPECL Output of 125 MHz
Parameter
Symbol
Minimum
Typical
Maximum
Unit
Phase noise at 100 Hz
phn100
-
-71
-
dBc/Hz
Phase noise at 1 kHz
phn1k
-
-75
-
dBc/Hz
Phase noise at 10 kHz
phn10k
-
-93
-
dBc/Hz
Phase noise at 100 kHz
phn100k
-
-124
-
dBc/Hz
Phase noise at 1 MHz
phn1M
-
-140
-
dBc/Hz
Phase noise at 10 MHz
phn10M
-
-142
-
dBc/Hz
Phase noise at 20 MHz
phn20M
-
-142
-
dBc/Hz
JRMS
-
4.6
-
ps
Tj
-
149
-
ps
RMS jitter integrated from 12 kHz to 20 MHz
Total jitter
Notes: (i) Phase noise specifications when fin = 62.5 MHz and fout = 125 MHz.
(ii) PLL closed loop bandwidth set to 2 kHz with a damping factor of 1.2.
(iii) Total jitter is broadband jitter accumulated over 100 s.
Table 20 Phase Noise Parameters with LVPECL Input of 19.44 MHz and LVPECL Output of 622.08 MHz
Parameter
Symbol
Minimum
Typical
Maximum
Unit
Phase noise at 100 Hz
phn100
-
-57
-
dBc/Hz
Phase noise at 1 kHz
phn1k
-
-66
-
dBc/Hz
Phase noise at 10 kHz
phn10k
-
-79
-
dBc/Hz
Phase noise at 100 kHz
phn100k
-
-110
-
dBc/Hz
Phase noise at 1 MHz
phn1M
-
-135
-
dBc/Hz
Phase noise at 10 MHz
phn10M
-
-142
-
dBc/Hz
Phase noise at 20 MHz
phn20M
-
-142
-
dBc/Hz
JRMS
-
4.3
-
ps
Tj
-
194
-
ps
RMS jitter integrated from 12 kHz to 20 MHz
Total jitter
Notes: (i) Phase noise specifications when fin = 19.44 MHz and fout = 622.08 MHz.
(ii) PLL closed loop bandwidth set to 2 kHz with a damping factor of 1.2.
(iii) Total jitter is broadband jitter accumulated over 100 s.
Revision 1.00/September 2007© Semtech Corp.
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Input/Output Timing
FINAL
DATASHEET
Page 25
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Figure 19 Timing Diagrams
Revision 1.00/September 2007© Semtech Corp.
ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Package Information
FINAL
DATASHEET
Page 26
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Figure 20 QFN48 Package.
Revision 1.00/September 2007© Semtech Corp.
ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Thermal Conditions
FINAL
The device is rated for full temperature range when this
package is used with a 4-layer or more PCB. Copper
coverage must exceed 50%. All pins must be soldered to
the PCB. Maximum operating temperature must be
reduced when the device is used with a PCB with less than
these requirements.
As the device includes a large thermal die paddle ground
connection which must be soldered to the PCB in addition
to the pins, giving improved pull-off strength and thermal
dissipation characteristics as well as the necessary
grounding.
DATASHEET
Although not essential for the ACS8947T, one technique
that may be used to improve heat dissipation from
through the large centre pad is to include a thermal
landing the same size as the centre pad on the
component side of the board (and one on the opposite
side of the PCB) connected to analog ground using a
number of thermal vias, approximately 0.33 mm
diameter. These vias should be completely connected
(flooded over) to the thermal landing(s) as well as to
internal ground planes if using a multi-layer PCB. 3 x 3
vias pitched at 1.27 mm between via centres would be
more than sufficient for the ACS8947T if this method
were adopted.
Figure 21 Typical 48 Pin QFN PCB Footprint
Revision 1.00/September 2007© Semtech Corp.
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Abbreviations
CML
CMU
ESD
ESR
HBM
I/O
JAM PLL
GbE
JAM PLL
LC/P
LDO
LVDS
LVPECL
OC-3/12/48
PECL
PFD
PLL
POR
p-p
rms
RoHS
SDH
SEC
SETS
SONET
STM-1/4/16
STS-12/48
UI
uP (μP)
VCO
WEEE
FINAL
DATASHEET
References and Related Standards
Current Mode Logic
Clock Multiplier Unit
Electrostatic Discharge
Effective Series Resistance
Human Body Model
Input - Output
Jitter Attenuating, Multiplying Phase
Locked Loop
Gigabit Ethernet
Jitter Attenuating, Multiplying PLL
Line Card Protection
Low Voltage Drop-out
Low Voltage Differential Signal
Low Voltage (3.3 V) PECL
Optical Carrier Signal Level 3/12/48
155.52 Mbps/ 622.08 Mbps/
2.488 Gbps
Positive Emitter Coupled Logic
Phase and Frequency Detector
Phase Locked Loop
Power-On Reset
peak-to-peak
root-mean-square
Restrictive Use of Certain Hazardous
Substances (directive)
Synchronous Digital Hierarchy
SDH/SONET Equipment Clock
Synchronous Equipment Timing source
Synchronous Optical Network
Synchronous Transport Module Levels
1/4/16: 155.52 Mbps/ 622.08 Mbps
2.488 Gbps (SDH)
Synchronous Transport Signal Level:
12/48, 622.08 Mbps/2.488 Gbps
(SONET)
Unit Interval
Microprocessor
Voltage Controlled Oscillator
Waste Electrical and Electronic
Equipment (directive)
Revision 1.00/September 2007© Semtech Corp.
[1] EN 300 462-7-1 v1.1.2 (06/2001)
Transmission and Multiplexing (TM); Generic
requirements for synchronization networks; Part 7-1:
Timing characteristics of slave clocks suitable for
synchronization supply to equipment in local node
applications
[2] ETSI EN 302 084 V1.1.1 (2000-02)
Transmission and Multiplexing (TM); The control of jitter
and wander in transport networks
[3] ITU-T G.812 (06/1998)
Timing requirements of slave clocks suitable for use as
node clocks in synchronization networks
[4] ITU-T G.813 (08/1996)
Timing characteristics of SDH equipment slave clocks
(SEC)
[5] ITU-T G.823 (03/2000)
The control of jitter and wander within digital networks
which are based on the 2048 kbit/s hierarchy
[6] ITU-T G.824 (03/2000)
The control of jitter and wander within digital networks
which are based on the 1544 kbit/s hierarchy
[7] ITU-T G.825 (03/2000)
The control of jitter and wander within digital networks
which are based on the Synchronous Digital Hierarchy
(SDH)
[8] Telcordia GR-253-CORE, Issue 3 (09/ 2000)
Synchronous Optical Network (SONET) Transport
Systems: Common Generic Criteria
[9] Telcordia GR-499-CORE, Issue 2 (12/1998)
Transport Systems Generic Requirements (TSGR)
Common requirements
[10] Telcordia GR-1244-CORE, Issue 2 (12/2000)
Clocks for the Synchronized Network: Common Generic
Criteria
[11] RoHS Directive 2002/95/EC: Directive 2002/95/EC
of the European Parliament and of the Council of 27
January 2003 on the restriction of the use of certain
hazardous substances in electrical and electronic
equipment
Page 28
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
FINAL
[12] Waste Electrical and Electronic Equipment (WEEE)
Revision Status/History
Directive (2002/96/EC): Directive 2002/96/EC of the
European Parliament and of the Council of 27 January
2003 on waste electrical and electronic equipment
(WEEE).
Trademark Acknowledgements
Semtech and the Semtech S logo are registered
trademarks of Semtech Corporation.
Telcordia is a registered trademark of Telcordia
Technologies.
DATASHEET
The Revision Status, as shown in top center of the
datasheet header bar, may be DRAFT, PRELIMINARY, or
FINAL, and refers to the status of the device (not the
datasheet), within the design cycle. DRAFT status is used
when the design is being realized but is not yet physically
available, and the datasheet content reflects the
intention of the design. The datasheet is raised to
PRELIMINARY status when initial prototype devices are
physically available, and the datasheet content more
accurately represents the realization of the design. The
datasheet is only raised to FINAL status after the device
has been fully characterized, and the datasheet content
updated with measured, rather than simulated parameter
values.
This is the FINAL release of the ACS8947T datasheet. The
changes made for this revision are given in Table 21.
Table 21 Revision History
Revision
Rev. 1.00/September 2007
Reference
All Pages
Revision 1.00/September 2007© Semtech Corp.
Description of Changes
First revision of FINAL release of ACS8947T datasheet.
Page 29
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ACS8947T JAM PLL
ADVANCED COMMS & SENSING
Ordering Information
FINAL
DATASHEET
Table 22 Parts List
Part Number
ACS8947T
Description
Lead (Pb)-free packaged version of ACS8947T.
Disclaimers
Life support - this product is not designed or intended for use in life support equipment, devices or systems, or other
critical applications, and is not authorized or warranted for such use.
Right to change - changes may be made to this product without notice. Customers are advised to obtain the latest
version of the relevant information before placing orders.
Compliance to relevant standards - operation of this device is subject to the user’s implementation and design
practices. It is the responsibility of users to ensure that equipment using this device is compliant to all relevant
standards.
Contact Information
Semtech Corporation Advanced Communications & Sensing Products
E-mail: [email protected]
[email protected]
Internet: http://www.semtech.com
USA
200 Flynn Road, Camarillo, CA 93012-8790.
Tel: +1 805 498 2111 Fax: +1 805 498 3804
FAR EAST
12F, No. 89 Sec. 5, Nanking E. Road, Taipei, 105, TWN, R.O.C.
Tel: +886 2 2748 3380 Fax: +886 2 2748 3390
EUROPE
Semtech Ltd., Units 2 & 3, Park Court, Premier Way, Abbey Park Industrial Estate, Romsey, Hampshire, SO51 9DN.
Tel: +44 (0)1794 527 600 Fax: +44 (0)1794 527 601
ISO9001
CERTIFIED
Revision 1.00/September 2007© Semtech Corp.
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