ZL30121GGG2V2

ZL30121
SONET/SDH
Low Jitter System Synchronizer
Data Sheet
June 2008
Features
•
•
Internal APLL provides standard output clock
frequencies up to 622.08 MHz with jitter < 3 ps
RMS suitable for GR-253-CORE OC-12 and G.813
STM-16 interfaces
•
Programmable output synthesizers generate clock
frequencies from any multiple of 8 kHz up to
77.76 MHz in addition to 2 kHz
•
Provides two DPLLs which are independently
configurable through a serial software interface
•
Ordering Information
Supports the requirements of Telcordia GR-253 and
GR-1244 for Stratum 3, 4E, 4 and SMC clocks, and
the requirements of ITU-T G.781 SETS, G.813
SEC, G.823, G.824 and G.825 clocks
ZL30121GGGV2
ZL30121GGG2V2
100 Pin CABGA
100 Pin CABGA**
Trays
Trays
**Pb Free Tin/Silver/Copper
-40oC to +85oC
DPLL1 provides all the features necessary for
generating SONET/SDH compliant clocks including
automatic hitless reference switching, automatic
mode selection (locked, free-run, holdover),
selectable loop bandwidth and pull-in range
•
Supports master/slave configuration for
AdvancedTCATM
•
Configurable input to output delay and output to
output phase alignment
•
Optional external feedback path provides dynamic
input to output delay compensation
•
Provides 3 sync inputs for output frame pulse
alignment
•
Generates several styles of output frame pulses
with selectable pulse width, polarity and frequency
•
DPLL2 provides a comprehensive set of features
necessary for generating derived output clocks and
other general purpose clocks
•
•
Provides 8 reference inputs which support clock
frequencies with any multiples of 8 kHz up to
77.76 MHz in addition to 2 kHz
Flexible input reference monitoring automatically
disqualifies references based on frequency and
phase irregularities
•
Supports IEEE 1149.1 JTAG Boundary Scan
trst_b tck tdi tms
osco
osci
Master
Clock
tdo
dpll2_ref
dpll1_hs_en
IEEE 1449.1
JTAG
dpll1_lock dpll1_holdover
DPLL2
diff0_en
diff1_en
P0
Synthesizer
p0_clk0
p0_clk1
p0_fp0
p0_fp1
P1
Synthesizer
p1_clk0
p1_clk1
ref
ref0
ref1
ref2
ref3
ref4
ref5
ref6
ref7
sync0
sync1
sync2
ref7:0
diff0_p/n
ref
diff1_p/n
DPLL1
sync2:0
sdh_clk0
sdh_clk1
sdh_fp0
sdh_fp1
Feedback
Synthesizer
fb_clk
sync
Reference
Monitors
int_b
SONET/SDH
APLL
fb_clk
ref_&_sync_status
fb_fp
ext_fb_fp
Controller &
State Machine
SPI Interface
ext_fb_clk
sck
si
so
cs_b
rst_b
slave_en
dpll1_mod_sel1:0
sdh_filter
filter_ref0
Figure 1 - Block Diagram
1
Zarlink Semiconductor Inc.
Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc.
Copyright 2006-2008, Zarlink Semiconductor Inc. All Rights Reserved.
filter_ref1
ZL30121
Applications
•
AdvancedTCATM Systems
•
Multi-Service Edge Switches or Routers
•
Multi-Service Provisioning Platforms (MSPPs)
•
Add-Drop Multiplexers (ADMs)
•
Wireless/Wireline Gateways
•
Wireless Base Stations
•
DSLAM / Next Gen DLC
•
Core Routers
2
Zarlink Semiconductor Inc.
Data Sheet
ZL30121
Data Sheet
Table of Contents
1.0 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
1.1 DPLL Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
1.2 DPLL Mode Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
1.3 Ref and Sync Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
1.4 Ref and Sync Monitoring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
1.5 Output Clocks and Frame Pulses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
1.6 Configurable Input-to-Output and Output-to-Output Delays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
1.7 Master/Slave Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
1.8 External Feedback Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
2.0 Software Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
3.0 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
3
Zarlink Semiconductor Inc.
ZL30121
Data Sheet
List of Figures
Figure 1 - Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Figure 2 - Automatic Mode State Machine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Figure 3 - Reference and Sync Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Figure 4 - Output Frame Pulse Alignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Figure 5 - Behaviour of the Guard Soak Timer during CFM or SCM Failures . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Figure 6 - Output Clock Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
Figure 7 - Phase Delay Adjustments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
Figure 8 - Typical Master/Slave Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Figure 9 - External Feedback Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
4
Zarlink Semiconductor Inc.
ZL30121
Data Sheet
List of Tables
Table 1 - DPLL1 and DPLL2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
Table 2 - Set of Pre-Defined Auto-Detect Clock Frequencies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Table 3 - Set of Pre-Defined Auto-Detect Sync Frequencies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Table 4 - Output Clock and Frame Pulse Frequencies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Table 5 - Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
5
Zarlink Semiconductor Inc.
ZL30121
Data Sheet
Change Summary
The following table captures the changes from the May 2006 issue.
Page
Item
Change
2
Ordering Information Box
Updated new ordering part numbers.
22
Table 5 -, “Register Map“
Corrected chip id_reg number.
6
Zarlink Semiconductor Inc.
ZL30121
Data Sheet
Pin Description
Pin #
Name
I/O
Type
Description
Input Reference
C1
B2
A3
C3
B3
B4
C4
A4
ref0
ref1
ref2
ref3
ref4
ref5
ref6
ref7
Id
Input References (LVCMOS, Schmitt Trigger). These are input references
available to both DPLL1 and DPLL2 for synchronizing output clocks. All eight
input references can be automatically or manually selected using software
registers. These pins are internally pulled down to Vss.
B1
A1
A2
sync0
sync1
sync2
Id
Frame Pulse Synchronization References (LVCMOS, Schmitt Trigger).
These are the frame pulse synchronization inputs associated with input
references 0, 1 and 2. These inputs accept frame pulses in a clock format (50%
duty cycle) or a basic frame pulse format with minimum pulse width of 5 ns.
These pins are internally pulled down to Vss.
C5
ext_fb_clk
Id
External DPLL Feedback Clock (LVCMOS, Schmitt Trigger). External
feedback clock input. This allows DPLL1 to adjust for PCB trace propagation
delays. This pin is internally pulled down to Vss. Leave open when not is use.
B5
ext_fb_fp
Id
External DPLL Feedback Frame Pulse (LVCMOS, Schmitt Trigger). External
feedback frame pulse input. This allows DPLL1 to adjust for PCB trace
propagation delays. This pin is internally pulled down to Vss. Leave open when
not is use.
Output Clocks and Frame Pulses
D10
sdh_clk0
O
SONET/SDH Output Clock 0 (LVCMOS). This output can be configured to
provide any one of the SONET/SDH clock outputs up to 77.76 MHz. The default
frequency for this output is 77.76 MHz.
G10
sdh_clk1
O
SONET/SDH Output Clock 1 (LVCMOS). This output can be configured to
provide any one of the SONET/SDH clock outputs up to 77.76 MHz. The default
frequency for this output is 19.44 MHz.
E10
sdh_fp0
O
SONET/SDH Output Frame Pulse 0 (LVCMOS). This output can be configured
to provide virtually any style of output frame pulse synchronized with an
associated SONET/SDH family output clock. The default frequency for this frame
pulse output is 8 kHz.
F10
sdh_fp1
O
SONET/SDH Output Frame Pulse 1 (LVCMOS). This output can be configured
to provide virtually any style of output frame pulse synchronized with an
associated SONET/SDH family output clock. The default frequency for this frame
pulse output is 2 kHz.
K9
p0_clk0
O
Programmable Synthesizer 0 - Output Clock 0 (LVCMOS). This output can be
configured to provide any frequency with a multiple of 8 kHz up to 77.76 MHz in
addition to 2 kHz. The default frequency for this output is 2.048 MHz.
K7
p0_clk1
O
Programmable Synthesizer 0 - Output Clock 1 (LVCMOS). This is a
programmable clock output configurable as a multiple or division of the p0_clk0
frequency within the range of 2 kHz to 77.76 MHz. The default frequency for this
output is 8.192 MHz.
7
Zarlink Semiconductor Inc.
ZL30121
Data Sheet
Pin #
Name
I/O
Type
K8
p0_fp0
O
Programmable Synthesizer 0 - Output Frame Pulse 0 (LVCMOS). This output
can be configured to provide virtually any style of output frame pulse associated
with the p0 clocks. The default frequency for this frame pulse output is 8 kHz.
J7
p0_fp1
O
Programmable Synthesizer 0 - Output Frame Pulse 1 (LVCMOS). This output
can be configured to provide virtually any style of output frame pulse associated
with the p0 clocks. The default frequency for this frame pulse output is 8 kHz
J10
p1_clk0
O
Programmable Synthesizer 1 - Output Clock 0 (LVCMOS). This output can be
configured to provide any frequency with a multiple of 8 kHz up to 77.76 MHz in
addition to 2 kHz. The default frequency for this output is 1.544 MHz (DS1).
K10
p1_clk1
O
Programmable Synthesizer1 - Output Clock 1 (LVCMOS). This is a
programmable clock output configurable as a multiple or division of the p1_clk0
frequency within the range of 2 kHz to 77.76 MHz. The default frequency for this
output is 3.088 MHz (2x DS1).
H10
fb_clk
O
Feedback Clock (LVCMOS). This output is a buffered copy of the feedback
clock for DPLL1. The frequency of this output always equals the frequency of the
selected reference.
E1
dpll2_ref
O
DPLL2 Selected Output Reference (LVCMOS). This is a buffered copy of the
output of the reference selector for DPLL2. Switching between input reference
clocks at this output is not hitless.
A9
B10
diff0_p
diff0_n
O
Differential Output Clock 0 (LVPECL). This output can be configured to provide
any one of the available SDH clocks. The default frequency for this clock output
is 155.52 MHz
A10
B9
diff1_p
diff1_n
O
Differential Output Clock 1 (LVPECL). This output can be configured to provide
any one of the available SDH clocks. The default frequency for this clock output
is 622.08 MHz clock
H5
rst_b
I
Reset (LVCMOS, Schmitt Trigger). A logic low at this input resets the device. To
ensure proper operation, the device must be reset after power-up. Reset should
be asserted for a minimum of 300 ns.
J5
dpll1_hs_en
Iu
DPLL1 Hitless Switching Enable (LVCMOS, Schmitt Trigger). A logic high at
this input enables hitless reference switching. A logic low disables hitless
reference switching and re-aligns DPLL1’s output phase to the phase of the
selected reference input. This feature can also be controlled through software
registers. This pin is internally pulled up to Vdd.
C2
D2
dpll1_mod_sel0
dpll1_mod_sel1
Iu
DPLL1 Mode Select 1:0 (LVCMOS, Schmitt Trigger). During reset, the levels
on these pins determine the default mode of operation for DPLL1 (Automatic,
Normal, Holdover or Freerun). After reset, the mode of operation can be
controlled directly with these pins, or by accessing the dpll1_modesel register
(0x1F) through the serial interface. This pin is internally pulled up to Vdd.
D1
slave_en
Iu
Master/Slave control (LVCMOS, Schmitt Trigger). This pin selects the mode of
operation for the device. If set high, slave mode is selected. If set low, master
mode is selected. This feature can also be controlled through software registers.
This pin is internally pulled up to Vdd.
Description
Control
8
Zarlink Semiconductor Inc.
ZL30121
Data Sheet
Pin #
Name
I/O
Type
K1
diff0_en
Iu
Differential Output 0 Enable (LVCMOS, Schmitt Trigger). When set high, the
differential LVPECL output 0 driver is enabled. When set low, the differential
driver is tristated reducing power consumption. This pin is internally pulled up to
Vdd.
D3
diff1_en
Iu
Differential Output 1 Enable (LVCMOS, Schmitt Trigger). When set high, the
differential LVPECL output 1 driver is enabled. When set low, the differential
driver is tristated reducing power consumption.This pin is internally pulled up to
Vdd.
H1
dpll1_lock
O
Lock Indicator (LVCMOS). This is the lock indicator pin for DPLL1. This output
goes high when DPLL1’s output is frequency and phase locked to the input
reference.
J1
dpll1_holdover
O
Holdover Indicator (LVCMOS). This pin goes high when DPLL1 enters the
holdover mode.
Description
Status
Serial Interface
E2
sck
I
Clock for Serial Interface (LVCMOS). Serial interface clock.
F1
si
I
Serial Interface Input (LVCMOS). Serial interface data input pin.
G1
so
O
Serial Interface Output (LVCMOS). Serial interface data output pin.
E3
cs_b
Iu
Chip Select for Serial Interface (LVCMOS). Serial interface chip select. This
pin is internally pulled up to Vdd.
G2
int_b
O
Interrupt Pin (LVCMOS). Indicates a change of device status prompting the
processor to read the enabled interrupt service registers (ISR). This pin is an
open drain, active low and requires an external pulled up to VDD.
APLL Loop Filter
A6
sdh_filter
A
External Analog PLL Loop Filter terminal.
B6
filter_ref0
A
Analog PLL External Loop Filter Reference.
C6
filter_ref1
A
Analog PLL External Loop Filter Reference.
JTAG and Test
J4
tdo
O
Test Serial Data Out (Output). JTAG serial data is output on this pin on the
falling edge of tck. This pin is held in high impedance state when JTAG scan is
not enabled.
K2
tdi
Iu
Test Serial Data In (Input). JTAG serial test instructions and data are shifted in
on this pin. This pin is internally pulled up to Vdd. If this pin is not used then it
should be left unconnected.
H4
trst_b
Iu
Test Reset (LVCMOS). Asynchronously initializes the JTAG TAP controller by
putting it in the Test-Logic-Reset state. This pin should be pulsed low on powerup to ensure that the device is in the normal functional state. This pin is internally
pulled up to Vdd. If this pin is not used then it should be connected to GND.
K3
tck
I
Test Clock (LVCMOS): Provides the clock to the JTAG test logic. If this pin is not
used then it should be pulled down to GND.
9
Zarlink Semiconductor Inc.
ZL30121
Data Sheet
Pin #
Name
I/O
Type
J3
tms
Iu
Test Mode Select (LVCMOS). JTAG signal that controls the state transitions of
the TAP controller. This pin is internally pulled up to VDD. If this pin is not used
then it should be left unconnected.
Description
Master Clock
K4
osci
I
Oscillator Master Clock Input (LVCMOS). This input accepts a 20 MHz
reference from a clock oscillator (TCXO, OCXO). The stability and accuracy of
the clock at this input determines the free-run accuracy and the long term
holdover stability of the output clocks.
K5
osco
O
Oscillator Master Clock Output (LVCMOS). This pin must be left unconnected
when the osci pin is connected to a clock oscillator.
Miscellaneous
J2
H7
J6
G3
IC
Internal Connection. Connect to ground.
K6
IC
Internal Connection. Leave unconnected.
F2
F3
NC
No Connection. Leave unconnected.
Power and Ground
D9
E4
G8
G9
J8
J9
H6
H8
VDD
P
P
P
P
P
P
P
P
Positive Supply Voltage. +3.3VDC nominal.
E8
F4
VCORE
P
P
Positive Supply Voltage. +1.8VDC nominal.
A5
A8
C10
AVDD
P
P
P
Positive Analog Supply Voltage. +3.3VDC nominal.
B7
B8
H2
AVCORE
P
P
P
Positive Analog Supply Voltage. +1.8VDC nominal.
10
Zarlink Semiconductor Inc.
ZL30121
I/O
Type
Description
Pin #
Name
D4
D5
D6
D7
E5
E6
E7
F5
F6
F7
G4
G5
G6
G7
E9
F8
F9
H9
VSS
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
G
Ground. 0 Volts.
A7
C7
C8
C9
D8
H3
AVSS
G
G
G
G
G
G
Analog Ground. 0 Volts.
IId Iu OAPG-
Data Sheet
Input
Input, Internally pulled down
Input, Internally pulled up
Output
Analog
Power
Ground
11
Zarlink Semiconductor Inc.
ZL30121
1.0
Data Sheet
Functional Description
The ZL30121 SONET/SDH System Synchronizer is a highly integrated device that provides the functionality
required for synchronizing network equipment. It incorporates two independent DPLLs, each capable of locking to
one of eight input references and provides a wide variety of synchronized output clocks and frame pulses.
1.1
DPLL Features
The ZL30121 provides two independently controlled Digital Phase-Locked Loops (DPLL1, DPLL2) for clock and/or
frame pulse synchronization. Table 1 shows a feature summary for both DPLLs.
Feature
DPLL1
DPLL2
Modes of Operation
Free-run, Normal (locked), Holdover
Free-run, Normal (locked), Holdover
Loop Bandwidth
User selectable: 0.1 Hz, 1.7 Hz, 3.5 Hz,
fast lock (7 Hz), 14 Hz, 28 Hz1, or
wideband2 (890 Hz / 56 Hz / 14 Hz)
Fixed: 14 Hz
Phase Slope Limiting
User selectable: 885 ns/s, 7.5 μs/s,
61 μs/s, or unlimited
User selectable: 61 μs/s, or unlimited
Pull-in Range
User selectable: 12 ppm, 52 ppm,
83 ppm, 130 ppm
Fixed: 130 ppm
Holdover Parameters
Selectable Update Times: 26 ms, 1 s,
10 s, 60 s, and Selectable Holdover
Post Filter BW: 18 mHz, 2.5 Hz, 10 Hz.
Fixed Update Time: 26 ms
No Holdover Post Filtering
Holdover Frequency
Accuracy
Better than 1 ppb (Stratum 3E) initial
frequency offset. Frequency drift
depends on the 20 MHz external
oscillator.
Better than 50 ppb (Stratum 3) initial
frequency offset. Frequency drift
depends on the 20 MHz external
oscillator.
Reference Inputs
Ref0 to Ref7
Ref0 to Ref7
Sync Inputs
Sync0, Sync1, Sync2
Sync inputs are not supported.
Input Ref Frequencies
2 kHz, N * 8 kHz up to 77.76 MHz
2 kHz, N * 8 kHz up to 77.76 MHz
Supported Sync Input
Frequencies
166.67 Hz, 400 Hz, 1 kHz, 2 kHz,
8 kHz, 64 kHz.
Sync inputs are not supported.
Input Reference
Selection/Switching
Automatic (based on programmable
priority and revertiveness), or manual
Automatic (based on programmable
priority and revertiveness), or manual
Hitless Ref Switching
Can be enabled or disabled
Can be enabled or disabled
Output Clocks
diff0_p/n, diff1_p/n, sdh_clk0, sdh_clk1,
p0_clk0, p0_clk1, p1_clk0, p1_clk1,
fb_clk.
p0_clk0, p0_clk1, p1_clk0, p1_clk1.
Output Frame Pulses
sdh_fp0, sdh_fp1, p0_fp0, p0_fp1
synchronized to active sync reference.
p0_fp0, p0_fp1 not synchronized to sync
reference.
Supported Output Clock
Frequencies
As listed in Table 4
As listed in Table 4 for p0_clk0, p0_clk1,
p1_clk0, p1_clk1
Table 1 - DPLL1 and DPLL2 Features
12
Zarlink Semiconductor Inc.
ZL30121
Feature
Data Sheet
DPLL1
DPLL2
Supported Output
Frame Pulse
Frequencies
As listed in Table 4
As listed in Table 4 for p0_fp0, p0_fp not
synchronized to sync reference.
External Status Pin
Indicators
Lock, Holdover
None
Table 1 - DPLL1 and DPLL2 Features
1. Limited to 14 Hz for 2 kHz references)
2. In the wideband mode, the loop bandwidth depends on the frequency of the reference input. For reference frequencies greater than
8 kHz, the loop bandwidth = 890 Hz. For reference frequencies equal to 8 kHz, the loop bandwidth = 56 Hz. The loop bandwidth is
equal to 14 Hz for reference frequencies of 2 kHz.
1.2
DPLL Mode Control
Both DPLL1 and DPLL2 independently support three modes of operation - free-run, normal, and holdover. The
mode of operation can be manually set or controlled by an automatic state machine as shown in Figure 2.
Reset
Free-Run
All references are monitored for
frequency accuracy and phase
regularity, and at least one
reference is qualified.
Lock
Acquisition
Another reference is
qualified and available
for selection
No references are
qualified and available
for selection
Phase lock on
the selected
reference is
achieved
Holdover
Selected reference
fails
Normal
Normal
(Locked)
(Locked)
Figure 2 - Automatic Mode State Machine
Free-run
The free-run mode occurs immediately after a reset cycle or when the DPLL has never been synchronized to a
reference input. In this mode, the frequency accuracy of the output clocks is equal to the frequency accuracy of the
external master oscillator.
Lock Acquisition
The input references are continuously monitored for frequency accuracy and phase regularity. If at least one of the
input references is qualified by the reference monitors, then the DPLL will begin lock acquisition on that input. Given
a stable reference input, the ZL30121 will enter in the Normal (locked) mode.
13
Zarlink Semiconductor Inc.
ZL30121
Data Sheet
Normal (locked)
The usual mode of operation for the DPLL is the normal mode where the DPLL phase locks to a selected qualified
reference input and generates output clocks and frame pulses with a frequency accuracy equal to the frequency
accuracy of the reference input. While in the normal mode, the DPLL’s clock and frame pulse outputs comply with
the MTIE and TDEV wander generation specifications as described in Telcordia and ITU-T telecommunication
standards.
Holdover
When the DPLL operating in the normal mode loses its reference input, and no other qualified references are
available, it will enter the holdover mode and continue to generate output clocks based on historical frequency data
collected while the DPLL was synchronized. The transition between normal and holdover modes is controlled by
the DPLL so that its initial frequency offset is better than 1 ppb which meets the requirement of Stratum 3E. The
frequency drift after this transition period is dependant on the frequency drift of the external master oscillator.
1.3
Ref and Sync Inputs
There are eight reference clock inputs (ref0 to ref7) available to both DPLL1 and DPLL2. The selected reference
input is used to synchronize the output clocks. Each of the DPLLs have independent reference selectors which can
be controlled using a built-in state machine or set in a manual mode.
DPLL2
ref7:0
DPLL1
sync2:0
Figure 3 - Reference and Sync Inputs
Each of the ref inputs accept a single-ended LVCMOS clock with a frequency ranging from 2 kHz to 77.76 MHz.
Built-in frequency detection circuitry automatically determines the frequency of the reference if its frequency is
within the set of pre-defined frequencies as shown in Table 2. Custom frequencies definable in multiples of 8 kHz
are also available.
2 kHz
16.384 MHz
8 kHz
19.44 MHz
64 kHz
38.88 MHz
1.544 MHz
77.76 MHz
2.048 MHz
6.48 MHz
8.192 MHz
Table 2 - Set of Pre-Defined Auto-Detect Clock Frequencies
14
Zarlink Semiconductor Inc.
ZL30121
Data Sheet
In addition to the reference inputs, DPLL1 has three optional frame pulse synchronization inputs (sync0 to sync2)
used to align the output frame pulses. The syncn input is selected with its corresponding refn input, where n = 0, 1,
or 2. Note that the sync input cannot be used to synchronize the DPLL, it only determines the alignment of the
frame pulse outputs. An example of output frame pulse alignment is shown in Figure 4.
Without a frame pulse
signal at the sync
input, the output
frame pulses will align
to any arbitrary cycle
of its associated
output clock.
When a frame pulse
signal is present at
the sync input, the
DPLL will align the
output frame pulses
to the output clock
edge that is aligned
to the input frame
pulse.
n = 0, 1, 2
x = 0, 1
refn
syncn - no frame pulse signal present
diffx/sdh_clkx/p0_clkx/p1_clkx
sdh_fpx/p0_fpx
n = 0, 1, 2
x = 0, 1
refn
syncn
diffx/sdh_clkx/p0_clkx/p1_clkx
sdh_fpx/p0_fpx
Figure 4 - Output Frame Pulse Alignment
Each of the sync inputs accept a single-ended LVCMOS frame pulse. Since alignment is determined from the rising
edge of the frame pulse, there is no duty cycle restriction on this input, but there is a minimum pulse width
requirement of 5 ns. Frequency detection for the sync inputs is automatic for the supported frame pulse frequencies
shown in Table 3.
166.67 Hz
(48x 125 μs frames)
400 Hz
1 kHz
2 kHz
8 kHz
64 kHz
Table 3 - Set of Pre-Defined Auto-Detect Sync Frequencies
15
Zarlink Semiconductor Inc.
ZL30121
1.4
Data Sheet
Ref and Sync Monitoring
All input references (ref0 to ref7) are monitored for frequency accuracy and phase regularity. New references are
qualified before they can be selected as a synchronization source and qualified references are continuously
monitored to ensure that they are suitable for synchronization. The process of qualifying a reference depends on
four levels of monitoring.
Single Cycle Monitor (SCM)
The SCM block measures the period of each reference clock cycle to detect phase irregularities or a missing clock
edge. In general, if the measured period deviates by more than 50% from the nominal period, then an SCM failure
(scm_fail) is declared.
Coarse Frequency Monitor (CFM)
The CFM block monitors the reference frequency over a measurement period of 30 μs so that it can quickly detect
large changes in frequency. A CFM failure (cfm_fail) is triggered when the frequency has changed by more than 3%
or approximately 30000 ppm.
Precise Frequency Monitor (PFM)
The PFM block measures the frequency accuracy of the reference over a 10 second interval. To ensure an
accurate frequency measurement, the PFM measurement interval is re-initiated if phase or frequency irregularities
are detected by the SCM or CFM. The PFM provides a level of hysteresis between the acceptance range and the
rejection range to prevent a failure indication from toggling between valid and invalid for references that are on the
edge of the acceptance range.
When determining the frequency accuracy of the reference input, the PFM uses the external oscillator’s output
frequency (focsi) as its point of reference.
Guard Soak Timer (GST)
The GST block mimics the operation of an analog integrator by accumulating failure events from the CFM and the
SCM blocks and applying a selectable rate of decay when no failures are detected.
As shown in Figure 5, a GST failure (gst_fail) is triggered when the accumulated failures have reached the upper
threshold during the disqualification observation window. When there are no CFM or SCM failures, the accumulator
decrements until it reaches its lower threshold during the qualification window.
CFM or SCM failures
ref
upper threshold
lower threshold
td
gst_fail
tq
td - disqualification time
tq - qualification time = n * td
Figure 5 - Behaviour of the Guard Soak Timer during CFM or SCM Failures
16
Zarlink Semiconductor Inc.
ZL30121
Data Sheet
All sync inputs (sync0 to sync2) are continuously monitored to ensure that there is a correct number of reference
clock cycles within the frame pulse period.
1.5
Output Clocks and Frame Pulses
The ZL30121 offers a wide variety of outputs including two low-jitter differential LVPECL clocks (diff0_p/n,
diff1_p/n), two SONET/SDH LVCMOS (sdh_clk0, sdh_clk1) output clocks, and four programmable LVCMOS
(p0_clk0, p0_clk1, p1_clk0, p1_clk1) output clocks. In addition to the clock outputs, two LVCMOS SONET/SDH
frame pulse outputs (sdh_fp0, sdh_fp1) and two LVCMOS programmable frame pulses (p0_fp0, p0_fp1) are also
available.
The feedback clock (fb_clk) of DPLL1 is available as an output clock. Its output frequency is always equal to
DPLL1’s selected input frequency.
The output clocks and frame pulses derived from the SONET/SDH APLL are always synchronous with DPLL1, and
the clocks and frame pulses generated from the programmable synthesizers can be synchronized to either DPLL1
or DPLL2. This allows the ZL30121 to have two independent timing paths.
P0
Synthesizer
p0_clk0
p0_fp0
p0_clk1
p0_fp1
P1
Synthesizer
p1_clk0
p1_clk1
DPLL2
diff0
diff1
SONET/SDH
APLL
DPLL1
Feedback
Synthesizer
Figure 6 - Output Clock Configuration
17
Zarlink Semiconductor Inc.
sdh_clk0
sdh_fp0
sdh_clk1
sdh_fp1
fb_clk
ZL30121
Data Sheet
The supported frequencies for the output clocks and frame pulses are shown in Table 4.
diff0_p/n,
diff1_p/n
(LVPECL)
sdh_clk0,
sdh_clk1
(LVCMOS)
p0_clk0, p1_clk0
(LVCMOS)
6.48 MHz
6.48 MHz
2 kHz
p0_clk1, p1_clk1
(LVCMOS)
sdh_fp0, shd_fp1,
p0_fp0, p0_fp1
(LVCMOS)
px_clk0
166.67 Hz
(48x 125 μs frames)
px_clk1 =
N * 8 kHz
(up to 77.76 MHz)2
2M
(Up to 77.76 MHz)1
400 Hz
19.44 MHz
9.72 MHz
38.88 MHz
12.96 MHz
1 kHz
51.84 MHz
19.44 MHz
2 kHz
77.76 MHz
25.92 MHz
4 kHz
155.52 MHz
38.88 MHz
8 kHz
311.04 MHz
51.84 MHz
32 kHz
622.08 MHz
77.76 MHz
64 kHz
Table 4 - Output Clock and Frame Pulse Frequencies
1. M= -128 to 127 defined as an 8-bit two’s complement value. +ve values divide, -ve values multiply
2. N = 0 to 9270, N = 0 selects 2 kH
18
Zarlink Semiconductor Inc.
ZL30121
1.6
Data Sheet
Configurable Input-to-Output and Output-to-Output Delays
The ZL30121 allows programmable static delay compensation for controlling input-to-output and output-to-output
delays of its clocks and frame pulses.
All of the output synthesizers (SONET/SDH, P0, P1, Feedback) locked to DPLL1 can be configured to lead or lag
the selected input reference clock using the DPLL1 Fine Delay. The delay is programmed in steps of 119.2 ps with
a range of -128 to +127 steps giving a total delay adjustment in the range of -15.26 ns to +15.14 ns. Negative
values delay the output clock, positive values advance the output clock. Synthesizers that are locked to DPLL2 are
unaffected by this delay adjustment.
In addition to the fine delay introduced in the DPLL1 path, the SONET/SDH, P0, and P1 synthesizers have the
ability to add their own fine delay adjustments using the P0 Fine Delay, P1 Fine Delay, and SDH Fine Delay.
These delays are also programmable in steps of 119.2 ps with a range of -128 to +127 steps.
In addition to these delays, the single-ended output clocks of the SONET/SDH, P0, and P1 synthesizers can be
independently offset by 90, 180 and 270 degrees using the Coarse Delay, and the SONET/SDH differential outputs
can be independently delayed by -1.6 ns, 0 ns, +1.6 ns or +3.2 ns using the Diff Delay. The output frame pulses
(SONET/SDH, P0) can be independently offset with respect to each other using the FP Delay.
DPLL2
P0
Synthesizer
P0 Fine Delay
Coarse Delay
p0_clk0
Coarse Delay
p0_clk1
FP Delay
FP Delay
P1
Synthesizer
P1 Fine Delay
DPLL1
SDH Fine Delay
SONET/SDH
APLL
p1_clk0
Coarse Delay
p1_clk1
Diff Delay
diff0
Diff Delay
diff1
Coarse Delay
sdh_clk0
Coarse Delay
sdh_clk1
FP Delay
Feedback
Synthesizer
Figure 7 - Phase Delay Adjustments
19
Zarlink Semiconductor Inc.
p0_fp1
Coarse Delay
FP Delay
DPLL1 Fine Delay
p0_fp0
sdh_fp0
sdh_fp1
fb_clk
ZL30121
1.7
Data Sheet
Master/Slave Configuration
In systems that provide redundant timing sources, it is desirable to minimize the output skew between the master
and the slave’s output clocks. This can be achieved by synchronizing the slave to one of the master’s output clocks
instead of synchronizing the slave to an external reference. If frame pulse alignment between the timing sources is
required, then the crossover link should consist of a clk/fp pair.
One method of connecting two ZL30121 devices in a master/slave configuration is shown in Figure 8 where there is
a dedicated crossover link between timing cards. Any of the master’s unused outputs and the slave’s unused inputs
can be used as a crossover link.
External
References
ref0
External
References
ref1
ref0
ref1
Crossover Link
ZL30121
(Master)
sdh_clk0
ref2
sdh_fp0
sync2
sdh_clk0
ref2
sync2
sdh_clk0
ZL30121
(Slave)
sdh_fp0
sdh_fp0
sdh_clk0
sdh_fp0
clk bus 1
fp bus 1
clk bus 2
fp bus 2
ref0 sync0
ref1 sync1
ref0 sync0
Line Card DPLL
(ZL30119,
ZL30117,
ZL30106)
ref1 sync1
Line Card DPLL
(ZL30119,
ZL30117,
ZL30106)
Figure 8 - Typical Master/Slave Configuration
20
Zarlink Semiconductor Inc.
ZL30121
1.8
Data Sheet
External Feedback Inputs
In addition to the static delay compensation described in the “External Feedback Inputs” section on page 21, the
ZL30121 also provides the option of dynamic delay compensation to minimize path delay variation associated with
external clock drivers and long PCB traces. This is accomplished by re-directing the internal DPLL1 feedback path
to external pins and closing the loop externally as shown in Figure 9.
ZL30121
DPLL1
clk_in
ref
fp_in
clk_out
clk
SONET/P0/P1
Synthesizers
fp
Path Delay
sync
fb_clk
fb_clk
Feedback
Synthesizer
fb_fp
fb_fp
ext_fb_fp
ext_fb_clk
realignment of input and output clocks
clk_in
fp_in
clk_out
fp_out
Figure 9 - External Feedback Configuration
21
Zarlink Semiconductor Inc.
fp_out
ZL30121
2.0
Data Sheet
Software Configuration
The ZL30121 is mainly controlled by accessing software registers through the serial peripheral interface (SPI). The
device can be configured to operate in a highly automated manner which minimizes its interaction with the system’s
processor, or it can operate in a manual mode where the system processor controls most of the operation of the
device.
The following table provides a summary of the registers available for status updates and configuration of the device.
.
Addr
(Hex)
Register
Name
Reset
Value
(Hex)
Description
Type
Miscellaneous Registers
00
id_reg
C5
Chip and version identification and reset ready
indication register
01
use_hw_ctrl
00
Allows some functions of the device to be
controlled by hardware pins
R
R/W
Interrupts
02
ref_fail_isr
FF
Reference failure interrupt service register
03
dpll1_isr
70
DPLL1 interrupt service register
Sticky
R
04
dpll2_isr
00
DPLL2 interrupt service register
Sticky
R
05
ref_mon_fail_0
FF
Ref0 and ref1 failure indications
Sticky
R
06
ref_mon_fail_1
FF
Ref2 and ref3 failure indications.
Sticky
R
07
ref_mon_fail_2
FF
Ref4 and ref5 failure indications
Sticky
R
08
ref_mon_fail_3
FF
Ref6 and ref7 failure indications
Sticky
R
09
ref_fail_isr_mask
00
Reference failure interrupt service register
mask
R/W
0A
dpll1_isr_mask
00
DPLL1 interrupt service register mask
R/W
0B
dpll2_isr_mask
00
DPLL2 interrupt service register mask
R/W
0C
ref_mon_fail_mask_0
FF
Control register to mask each failure indicator
for ref0 and ref1
R/W
0D
ref_mon_fail_mask_1
FF
Control register to mask each failure indicator
for ref2 and ref3
R/W
0E
ref_mon_fail_mask_2
FF
Control register to mask each failure indicator
for ref4 and ref5
R/W
Table 5 - Register Map
22
Zarlink Semiconductor Inc.
R
ZL30121
Addr
(Hex)
0F
Register
Name
ref_mon_fail_mask_3
Reset
Value
(Hex)
FF
Data Sheet
Description
Control register to mask each failure indicator
for ref6 and ref7
Type
R/W
Reference Monitor Setup
10
detected_ref_0
FF
Ref0 and ref1 auto-detected frequency value
status register
R
11
detected_ref_1
FF
Ref2 and ref3 auto-detected frequency value
status register
R
12
detected_ref_2
FF
Ref4 and ref5 auto-detected frequency value
status register
R
13
detected_ref_3
FF
Ref6 and ref7 auto-detected frequency value
status register
R
14
detected_sync_0
EE
Sync0 and sync1 auto-detected frequency
value and sync failure status register
R
15
detected_sync_1
0E
Sync2 auto-detected frequency value and sync
valid status register
R
16
oor_ctrl_0
33
Control register for the ref0 and ref1 out of
range limit
R/W
17
oor_ctrl_1
33
Control register for the ref2 and ref3 out of
range limit
R/W
18
oor_ctrl_2
33
Control register for the ref4 and ref5 out of
range limit
R/W
19
oor_ctrl_3
33
Control register for the ref6 and ref7 out of
range limit
R/W
1A
gst_mask_0
FF
Control register to mask the inputs to the guard
soak timer for ref0 to ref3
R/W
1B
gst_mask_1
FF
Control register to mask the inputs to the guard
soak timer for ref4 to ref7
R/W
1C
gst_qualif_time
1A
Control register for the guard_soak_timer
qualification time and disqualification time for
the references
R/W
DPLL1 Control
1D
dpll1_ctrl_0
See
Register
Description
Control register for the DPLL1 filter control;
phase slope limit, bandwidth and hitless
switching
R/W
1E
dpll1_ctrl_1
See
Register
Description
Holdover update time, filter_out_en,
freq_offset_en, revert enable
R/W
Table 5 - Register Map (continued)
23
Zarlink Semiconductor Inc.
ZL30121
Addr
(Hex)
Register
Name
1F
dpll1_modesel
20
Reset
Value
(Hex)
Data Sheet
Description
Type
See
Register
Description
Control register for the DPLL1 mode of
operation
R/W
dpll1_refsel
00
DPLL1 reference selection or reference
selection status
R/W
21
dpll1_ref_fail_mask
3C
Control register to mask each failure indicator
(SCM, CFM, PFM and GST) used for automatic
reference switching and automatic holdover
R/W
22
dpll1_wait_to_restore
00
Control register to indicate the time to restore a
previous failed reference
R/W
23
dpll1_ref_rev_ctrl
00
Control register for the ref0 to ref7 enable
revertive signals
R/W
24
dpll1_ref_pri_ctrl_0
10
Control register for the ref0 and ref1 priority
values
R/W
25
dpll1_ref_pri_ctrl_1
32
Control register for the ref2 and ref3 priority
values
R/W
26
dpll1_ref_pri_ctrl_2
54
Control register for the ref4 and re5 priority
values
R/W
27
dpll1_ref_pri_ctrl_3
76
Control register for the ref6 and ref7 priority
values
R/W
28
dpll1_lock_holdover_status
04
DPLL1 lock and holdover status register
29
dpll1_pullinrange
03
Control register for the pull-in range
R
R/W
DPLL2 Control
2A
dpll2_ctrl_0
00
Control register to program the DPLL2: hitless
switching, the phase slope limit and DPLL
enable
R/W
2B
dpll2_ctrl_1
04
Control register to program the DPLL2:
filter_out_en, freq_offset_en, revert enable
R/W
2C
dpll2_modesel
02
Control register to select the mode of operation
of the DPLL2
R/W
2D
dpll2_refsel
00
DPLL2 reference selection or reference
selection status
R/W
2E
dpll2_ref_fail_mask
3C
Control register to mask each failure indicator
(SCM, CFM, PFM and GST) used for automatic
reference switching and automatic holdover
R/W
2F
dpll2_wait_to_restore
00
Control register to indicate the time to restore a
previous failed reference for the DPLL2 path
R/W
30
dpll2_ref_rev_ctrl
00
Control register for the ref0 to ref7 enable
revertive signals
R/W
Table 5 - Register Map (continued)
24
Zarlink Semiconductor Inc.
ZL30121
Addr
(Hex)
Register
Name
Reset
Value
(Hex)
Data Sheet
Description
Type
31
dpll2_ref_pri_ctrl_0
10
Control register for the ref0 and ref1 priority
values
R/W
32
dpll2_ref_pri_ctrl_1
32
Control register for the ref2 and ref3 priority
values
R/W
33
dpll2_ref_pri_ctrl_2
54
Control register for the ref4 and re5 priority
values
R/W
34
dpll2_ref_pri_ctrl_3
76
Control register for the ref6 and ref7 priority
values
R/W
35
dpll2_lock_holdover_status
04
DPLL2 lock and holdover status register
R
P0 Configuration Registers
36
p0_enable
8F
Control register to enable p0_clk0, p0_clk1,
p0_fp0, p0_fp1, the P0 synthesizer and select
the source
R/W
37
p0_run
0F
Control register to generate p0_clk0, p0_clk1,
p0_fp0 and p0_fp1
R/W
38
p0_freq_0
00
Control register for the [7:0] bits of the N of
N*8k clk0
R/W
39
p0_freq_1
01
Control register for the [13:8] bits of the N of
N*8k clk0
R/W
3A
p0_clk0_offset90
00
Control register for the p0_clk0 phase position
coarse tuning
R/W
3B
p0_clk1_div
3E
Control register for the p0_clk1 frequency
selection
R/W
3C
p0_clk1_offset90
00
Control register for the p0_clk1 phase position
coarse tuning
R/W
3D
p0_offset_fine
00
Control register for the output/output phase
alignment fine tuning for p0 path
R/W
3E
p0_fp0_freq
05
Control register to select the p0_fp0 frame
pulse frequency
R/W
3F
p0_fp0_type
83
Control register to select fp0 type
R/W
40
p0_fp0_fine_offset_0
00
Bits [7:0] of the programmable frame pulse
phase offset in multiples of 1/262.14 MHz
R/W
41
p0_fp0_fine_offset_1
00
Bits [15:8] of the programmable frame pulse
phase offset in multiples of 1/262.14 MHz
R/W
42
p0_fp0_coarse_offset
00
Programmable frame pulse phase offset in
multiples of 8 kHz cycles
R/W
43
p0_fp1_freq
05
Control register to select p0_fp1 frame pulse
frequency
R/W
Table 5 - Register Map (continued)
25
Zarlink Semiconductor Inc.
ZL30121
Addr
(Hex)
Register
Name
Reset
Value
(Hex)
Data Sheet
Description
Type
44
p0_fp1_type
11
Control register to select fp1 type
R/W
45
p0_fp1_fine_offset_0
00
Bits [7:0] of the programmable frame pulse
phase offset in multiples of 1/262.144 MHz
R/W
46
p0_fp1_fine_offset_1
00
Bits [15:8] of the programmable frame pulse
phase offset in multiples of 1/262.144 MHz
R/W
47
p0_fp1_coarse_offset
00
Programmable frame pulse phase offset in
multiples of 8 kHz cycles
R/W
P1 Configuration Registers
48
p1_enable
83
Control register to enable p1_clk0, p1_clk1, the
P1 synthesizer and select the source
R/W
49
p1_run
03
Control register to generate enable/disable
p1_clk0 and p1_clk1
R/W
4A
p1_freq_0
C1
Control register for the [7:0] bits of the N of
N*8k clk0
R/W
4B
p1_freq_1
00
Control register for the [13:8] bits of the N of
N*8k clk0
R/W
4C
p1_clk0_offset90
00
Control register for the p1_clk0 phase position
coarse tuning
R/W
4D
p1_clk1_div
3F
Control register for the p1_clk1 frequency
selection
R/W
4E
p1_clk1_offset90
00
Control register for the p1_clk1 phase position
coarse tuning
R/W
4F
p1_offset_fine
00
Control register for the output/output phase
alignrment fine tuning
R/W
SDH Configuration Registers
50
sdh_enable
8F
Control register to enable sdh_clk0, sdh_clk1,
sdh_fp0, sdh_fp1 and the SDH PLL
R/W
51
sdh_run
0F
Control register to generate sdh_clk0,
sdh_clk1, sdh_fp0 and sdh_fp1
R/W
52
sdh_clk_div
42
Control register for the sdh_clk0 and sdh_clk1
frequency selection
R/W
53
sdh_clk0_offset90
00
Control register for the sdh_clk0 phase position
coarse tuning
R/W
54
sdh_clk1_offset90
00
Control register for the sdh_clk1 phase position
coarse tuning
R/W
55
sdh_offset_fine
00
Control register for the output/output phase
alignrment fine tuning for sdh path
R/W
Table 5 - Register Map (continued)
26
Zarlink Semiconductor Inc.
ZL30121
Addr
(Hex)
Register
Name
Reset
Value
(Hex)
Data Sheet
Description
Type
56
sdh_fp0_freq
05
Control register to select the sdh_fp0 frame
pulse frequency
R/W
57
sdh_fp0_type
23
Control register to select fp0 type
R/W
58
sdh_fp0_fine_offset_0
00
Bits [7:0] of the programmable frame pulse
phase offset in multiples of 1/311.04 MHz
R/W
59
sdh_fp0_fine_offset_1
00
Bits [15:8] of the programmable frame pulse
phase offset in multiples of 1/311.04 MHz
R/W
5A
sdh_fp0_coarse_offset
00
Programmable frame pulse phase offset in
multiples of 8 kHz cycles
R/W
5B
sdh_fp1_freq
03
Control register to select sdh_fp1 frame pulse
frequency
R/W
5C
sdh_fp1_type
03
Control register to select fp1 type
R/W
5D
sdh_fp1_fine_offset_0
00
Bits [7:0] of the programmable frame pulse
phase offset in multiples of 1/311.04 MHz
R/W
5E
sdh_fp1_fine_offset_1
00
Bits [15:8] of the programmable frame pulse
phase offset in multiples of 1/311.04 MHz
R/W
5F
sdh_fp1_coarse_offset
00
Programmable frame pulse phase offset in
multiples of 8 kHz cycles
R/W
Differential Output Configuration
60
diff_ctrl
A3
Control register to enable diff0, diff1
R/W
61
diff_sel
53
Control register to select the diff0 and diff1
frequencies
R/W
External Feedback Configuration
62
fb_control
80
Control register to enable fb_clk and the FB
PLL, int/ext feedback select
R/W
63
fb_offset_fine
F5
Control register for the output/output phase
alignment fine tuning
R/W
64
reserved
N * 8 kHz Reference Control
65
ref_freq_mode_0
00
Control register to set whether to use auto
detect, CustomA or CustomB for ref0 to ref3
R/W
66
ref_freq_mode_1
00
Control register to set whether to use auto
detect, CustomA or CustomB for ref4 to ref7
R/W
67
custA_mult_0
00
Control register for the [7:0] bits of the custom
configuration A. This is the N integer for the
N*8kHz reference monitoring.
R/W
Table 5 - Register Map (continued)
27
Zarlink Semiconductor Inc.
ZL30121
Addr
(Hex)
Register
Name
Reset
Value
(Hex)
Data Sheet
Description
Type
68
custA_mult_1
00
Control register for the [13:8] bits of the custom
configuration A. This is the N integer for the
N*8kHz reference monitoring.
R/W
69
custA_scm_low
00
Control register for the custom configuration A:
single cycle SCM low limiter
R/W
6A
custA_scm_high
00
Control register for the custom configuration
A: single cycle SCM high limiter
R/W
6B
custA_cfm_low_0
00
Control register for the custom configuration
A: The [7:0] bits of the single cycle CFM low
limit
R/W
6C
custA_cfm_low_1
00
Control register for the custom configuration
A: The [15:0] bits of the single cycle CFM low
limit
R/W
6D
custA_cfm_hi_0
00
Control register for the custom configuration
A: The [7:0] bits of the single cycle CFM high
limit
R/W
6E
custA_cfm_hi_1
00
Control register for the custom configuration
A: The [15:0] bits of the single cycle CFM high
limiter
R/W
6F
custA_cfm_cycle
00
Control register for the custom configuration
A: CFM reference monitoring cycles - 1
R/W
70
custA_div
00
Control register for the custom configuration
A: enable the use of ref_div4 for the CFM and
PFM inputs
R/W
71
custB_mult_0
00
Control register for the [7:0] bits of the custom
configuration B. This is the 8 k integer for the
N*8kHz reference monitoring.
R/W
72
custB_mult_1
00
Control register for the [13:8] bits of the custom
configuration B. This is the 8 k integer for the
N*8kHz reference monitoring.
R/W
73
custB_scm_low
00
Control register for the custom configuration B:
single cycle SCM low limiter
R/W
74
custB_scm_high
00
Control register for the custom configuration
B: single cycle SCM high limiter
R/W
75
custB_cfm_low_0
00
Control register for the custom configuration
B: The [7:0] bits of the single cycle CFM low
limiter.
R/W
76
custB_cfm_low_1
00
Control register for the custom configuration
B: The [15:0] bits of the single cycle CFM low
limiter.
R/W
Table 5 - Register Map (continued)
28
Zarlink Semiconductor Inc.
ZL30121
Addr
(Hex)
Register
Name
Reset
Value
(Hex)
Data Sheet
Description
Type
77
custB_cfm_hi_0
00
Control register for the custom configuration
B: The [7:0] bits of the single cycle CFM high
limiter.
R/W
78
custB_cfm_hi_1
00
Control register for the custom configuration
B: The [15:0] bits of the single cycle CFM high
limiter.
R/W
79
custB_cfm_cycle
00
Control register for the custom configuration
B: CFM reference monitoring cycles - 1
R/W
7A
custB_div
00
Control register for the custom configuration
B: enable the use of ref_div4 for the CFM and
PFM inputs
R/W
7B 7F
Reserved
Table 5 - Register Map (continued)
3.0
References
AdvancedTCA, ATCA and the AdvancedTCA and ATCA logos are trademarks of the PCI Industrial Computer
Manufacturers Group.
29
Zarlink Semiconductor Inc.
For more information about all Zarlink products
visit our Web Site at
www.zarlink.com
Information relating to products and services furnished herein by Zarlink Semiconductor Inc. or its subsidiaries (collectively “Zarlink”) is believed to be reliable.
However, Zarlink assumes no liability for errors that may appear in this publication, or for liability otherwise arising from the application or use of any such
information, product or service or for any infringement of patents or other intellectual property rights owned by third parties which may result from such application or
use. Neither the supply of such information or purchase of product or service conveys any license, either express or implied, under patents or other intellectual
property rights owned by Zarlink or licensed from third parties by Zarlink, whatsoever. Purchasers of products are also hereby notified that the use of product in
certain ways or in combination with Zarlink, or non-Zarlink furnished goods or services may infringe patents or other intellectual property rights owned by Zarlink.
This publication is issued to provide information only and (unless agreed by Zarlink in writing) may not be used, applied or reproduced for any purpose nor form part
of any order or contract nor to be regarded as a representation relating to the products or services concerned. The products, their specifications, services and other
information appearing in this publication are subject to change by Zarlink without notice. No warranty or guarantee express or implied is made regarding the
capability, performance or suitability of any product or service. Information concerning possible methods of use is provided as a guide only and does not constitute
any guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user’s responsibility to fully determine the performance and
suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not been superseded. Manufacturing does
not necessarily include testing of all functions or parameters. These products are not suitable for use in any medical products whose failure to perform may result in
significant injury or death to the user. All products and materials are sold and services provided subject to Zarlink’s conditions of sale which are available on request.
Purchase of Zarlink’s I2C components conveys a license under the Philips I2C Patent rights to use these components in and I2C System, provided that the system
conforms to the I2C Standard Specification as defined by Philips.
Zarlink, ZL, the Zarlink Semiconductor logo and the Legerity logo and combinations thereof, VoiceEdge, VoicePort, SLAC, ISLIC, ISLAC and VoicePath are
trademarks of Zarlink Semiconductor Inc.
TECHNICAL DOCUMENTATION - NOT FOR RESALE