ZARLINK ZL30105

ZL30105
T1/E1/SDH Stratum 3 Redundant System Clock
Synchonizer for AdvancedTCA™ and H.110
Data Sheet
Features
June 2004
•
Synchronizes to clock-and-sync-pair to maintain
minimal phase skew between the master-clock
and the redundant slave-clock
•
Supports ITU-T G.813 option 1, G.823 for 2048 kbs
and G.824 for 1544 kbs interfaces
•
Supports Telcordia GR-1244-CORE Stratum
3/4/4E
•
Supports ANSI T1.403 and ETSI ETS 300 011 for
ISDN primary rate interfaces
•
Accepts three input references and synchronizes
to any combination of 2 kHz, 8 kHz, 1.544 MHz,
2.048 MHz, 8.192 MHz, 16.384 MHz or 19.44 MHz
inputs
•
Ordering Information
ZL30105QDG
-40°C to +85°C
Provides a range of clock outputs: 1.544 MHz
(DS1), 2.048 MHz (E1), 3.088 MHz, 16.384 MHz,
and 19.44 MHz (SDH), and either 4.096 MHz and
8.192 MHz or 32.768 MHz and 65.536 MHz, and a
choice of 6.312 MHz (DS2), 8.448 MHz (E2),
44.736 MHz (DS3) or 34.368 MHz (E3)
•
Provides 5 styles of 8 kHz framing pulses and a
2 kHz multi-frame pulse
•
Holdover frequency accuracy of 1x10-8
•
Selectable loop filter 1.8 Hz, 3.6 Hz or 922 Hz
•
Less than 20 psrms intrinsic jitter on the 19.44 MHz
output clock, compliant with GR-253-CORE OC-3
and G.813 STM-1 specifications
OSCi
OSCo
64 pin TQFP
•
Less than 0.6 nspp intrinsic jitter on all output
clocks and frame pulses
•
Manual or Automatic hitless reference switching
•
Provides Lock, Holdover and selectable Out of
Range indication
•
Simple hardware control interface
•
Selectable external master clock source: Clock
Oscillator or Crystal
Applications
•
Synchronization and timing control for multi-trunk
SDH and T1/E1 systems such as DSLAMs,
Gateways and PBXs
•
Clock and frame pulse source for
AdvancedTCA™- and other time division
multiplex (TDM) buses
FASTLOCK
TIE_CLR
LOCK
OUT_SEL2
Master Clock
REF0
REF1
TIE
Corrector
Circuit
MUX
REF2
Virtual
Reference
DPLL
E1
Synthesizer
REF2_SYNC
REF_FAIL0
REF_FAIL1
REF_FAIL2
TIE
Corrector
Enable
Reference
Monitor
DS1
Synthesizer
Mode
Control
REF_SEL1:0
State Machine
RST
MODE_SEL1:0
HMS
Frequency
Select
MUX
HOLDOVER
SEC_MSTR
APP_SEL1:0
SDH
Synthesizer
Programmable
Synthesizer
IEEE
1149.1a
TCK
TDI TMS TDO
Figure 1 - Functional Block Diagram
1
Zarlink Semiconductor Inc.
Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc.
Copyright 2004, Zarlink Semiconductor Inc. All Rights Reserved.
C2o
C4/C65o
C8/C32o
C16o
F4/F65o
F8/F32o
F16o
C1.5o
C3o
C19o
F2ko
C6/8.4/34/44o
OUT_SEL1:0
TRST
ZL30105
Data Sheet
Description
The ZL30105 SDH/PDH System Synchronizer contains a digital phase-locked loop (DPLL), which provides timing
and synchronization for SDH and T1/E1 transmission equipment. It provides advanced support for systems
deploying redundant clocks.
The ZL30105 generates SBI, ST-BUS and other TDM clock and framing signals that are phase locked to one of
three network references or to a system master-clock reference. It helps ensure system reliability by monitoring its
references for frequency accuracy and stability and by maintaining tight phase alignment between the master-clock
and slave-clock outputs even in the presence of high network jitter.
The ZL30105 is intended to be the central timing and synchronization resource for network equipment that
complies with ITU-T, Telcordia, ETSI and ANSI network specifications.
2
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Table of Contents
1.0 Pin Description. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
2.0 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
2.1 Reference Select Multiplexer (MUX) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
2.2 Reference Monitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
2.3 Time Interval Error (TIE) Corrector Circuit. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
2.4 Digital Phase Lock Loop (DPLL) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
2.5 Frequency Synthesizers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
2.6 State Machine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
2.7 Master Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
3.0 Control and Modes of Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
3.1 Application Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
3.2 Loop Filter and Limiter Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
3.3 Output Clock and Frame Pulse Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
3.4 Modes of Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
3.4.1 Freerun Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
3.4.2 Holdover Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
3.4.3 Normal Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
3.4.4 Automatic Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
3.5 Reference Switching . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
3.5.1 Manual Reference Switching . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
3.5.2 Automatic Reference Switching . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
3.5.2.1 Automatic Reference Switching - Coarse Reference Failure . . . . . . . . . . . . . . . . . . . . . . . . . 23
3.5.2.2 Automatic Reference Switching - Reference Frequency Out-of-Range . . . . . . . . . . . . . . . . . 24
3.6 Clock Redundancy Support. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
4.0 Measures of Performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
4.1 Jitter. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
4.2 Jitter Generation (Intrinsic Jitter) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
4.3 Jitter Tolerance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
4.4 Jitter Transfer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
4.5 Frequency Accuracy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
4.6 Holdover Accuracy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
4.7 Pull-in Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
4.8 Lock Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
4.9 Phase Slope . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
4.10 Time Interval Error (TIE) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
4.11 Maximum Time Interval Error (MTIE) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
4.12 Phase Continuity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
4.13 Lock Time . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
5.0 Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
5.1 Power Supply Decoupling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
5.2 Master Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
5.2.1 Clock Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
5.2.2 Crystal Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
5.3 Power Up Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
5.4 Reset Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
5.5 Clock Redundancy System Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
6.0 Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
6.1 AC and DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
6.2 Performance Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
7.0 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
List of Figures
Figure 1 - Functional Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Figure 2 - Pin Connections (64 pin TQFP). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Figure 3 - Reference Monitor Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Figure 4 - Behaviour of the Dis/Re-qualify Timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Figure 5 - DS1 Out-of-Range Thresholds for APP_SEL1:0=00. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
Figure 6 - E1 Out-of-Range Thresholds for APP_SEL=01 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
Figure 7 - Out-of-Range Thresholds for APP_SEL=10 and APP_SEL=11 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Figure 8 - REF2_SYNC Reference Monitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Figure 9 - Timing Diagram of Hitless Reference Switching . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Figure 10 - Timing Diagram of Hitless Mode Switching . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Figure 11 - DPLL Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Figure 12 - Mode Switching in Normal Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
Figure 13 - Reference Switching in Normal Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Figure 14 - Reference Selection in Automatic Mode (MODE_SEL=11). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Figure 15 - Mode Switching in Automatic Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
Figure 16 - Automatic Reference Switching - Coarse Reference Failure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
Figure 17 - Automatic Reference Switching - Out-of-Range Reference Failure . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Figure 18 - Examples of REF2 & REF2_SYNC to Output Alignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
Figure 19 - Clock Redundancy with Two Independent Timing Cards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
Figure 20 - Recommended Power Supply Decoupling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Figure 21 - Clock Oscillator Circuit. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
Figure 22 - Crystal Oscillator Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
Figure 23 - Power-Up Reset Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
Figure 24 - Typical Clocking Architecture of an ECTF H.110 System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Figure 25 - Typical Clocking Architecture of a PICMG AdvancedTCA™ System . . . . . . . . . . . . . . . . . . . . . . . . . 35
Figure 26 - Timing Parameter Measurement Voltage Levels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
Figure 27 - REF0/1/2 Input Timing and Input to Output Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
Figure 28 - REF2_SYNC Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
Figure 29 - E1 Output Timing Referenced to F8/F32o. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
Figure 30 - DS1 Output Timing Referenced to F8/F32o . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
Figure 31 - SDH Output Timing Referenced to F8/F32o . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
Figure 32 - DS3, E3, E2 and DS2 Output Timing Referenced to F8/F32o . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
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Zarlink Semiconductor Inc.
ZL30105
F8/F32o
C16o
C2o
AVDD
AVDD
C8/C32o
C4/C65o
AGND
AGND
C19o
F2ko
AVDD
AVDD
AVCORE
AGND
AGND
Data Sheet
48
46
44
42
40
38
36
34
32
50
30
52
28
54
26
56
ZL30105
24
58
22
60
20
62
18
64
2
4
6
8
10
12
14
C1.5o
C3o
C6/8.4/34/44o
AVDD
OUT_SEL0
OUT_SEL1
OUT_SEL2
VDD
APP_SEL1
GND
IC
OSCi
OSCo
RST
MODE_SEL1
MODE_SEL0
16
GND
VCORE
LOCK
HOLDOVER
REF_FAIL0
REF_FAIL1
REF_FAIL2
TDO
TMS
TRST
TCK
VCORE
GND
AVCORE
TDI
HMS
F4/F65o
F16o
AGND
IC
REF_SEL0
REF_SEL1
REF0
REF1
REF2
REF2_SYNC
SEC_MSTR
APP_SEL0
VDD
IC
TIE_CLR
FASTLOCK
Figure 2 - Pin Connections (64 pin TQFP)
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Zarlink Semiconductor Inc.
ZL30105
1.0
Data Sheet
Pin Description
Pin #
Name
Description
1
GND
2
VCORE
Positive Supply Voltage. +1.8 VDC nominal
3
LOCK
Lock Indicator (Output). This output goes to a logic high when the PLL is frequency
locked to the selected input reference.
4
HOLDOVER
Holdover (Output). This output goes to a logic high whenever the PLL goes into
holdover mode.
5
REF_FAIL0
Reference 0 Failure Indicator (Output). A logic high at this pin indicates that the REF0
reference frequency has exceeded the out-of-range limit set by the APP_SEL pins or that
it is exhibiting abrupt phase or frequency changes.
6
REF_FAIL1
Reference 1 Failure Indicator (Output). A logic high at this pin indicates that the REF1
reference frequency has exceeded the out-of-range limit set by the APP_SEL pins or that
it is exhibiting abrupt phase or frequency changes.
7
REF_FAIL2
Reference 2 Failure Indicator (Output). A logic high at this pin indicates that the REF2
reference frequency has exceeded the out-of-range limit set by the APP_SEL pins or that
it is exhibiting abrupt phase or frequency changes.
8
TDO
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.
9
TMS
Test Mode Select (Input). 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.
10
TRST
Test Reset (Input). Asynchronously initializes the JTAG TAP controller by putting it in the
Test-Logic-Reset state. This pin should be pulsed low on power-up 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.
11
TCK
Test Clock (Input): Provides the clock to the JTAG test logic. If this pin is not used then it
should be pulled down to GND.
12
VCORE
13
GND
14
AVCORE
15
TDI
16
HMS
Ground. 0 V
Positive Supply Voltage. +1.8 VDC nominal
Ground. 0 V
Positive Analog Supply Voltage. +1.8 VDC nominal
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.
Hitless Mode Switching (Input). The HMS input controls phase accumulation during the
transition from Holdover or Freerun mode to Normal mode on the same reference. A logic
low at this pin will cause the ZL30105 to maintain the delay stored in the TIE corrector
circuit when it transitions from Holdover or Freerun mode to Normal mode. A logic high
on this pin will cause the ZL30105 to measure a new delay for its TIE corrector circuit
thereby minimizing the output phase movement when it transitions from Holdover or
Freerun mode to Normal mode.
17
MODE_SEL0 Mode Select 0 (Input). This input combined with MODE_SEL1 determines the mode of
operation, see Table 4 on page 19.
18
MODE_SEL1 Mode Select 1 (Input). See MODE_SEL0 pin description.
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Pin #
Name
Description
19
RST
Reset (Input). A logic low at this input resets the device. On power up, the RST pin must
be held low for a minimum of 300 ns after the power supply pins have reached the
minimum supply voltage. When the RST pin goes high, the device will transition into a
Reset state for 3 ms. In the Reset state all outputs will be forced into high impedance.
20
OSCo
Oscillator Master Clock (Output). For crystal operation, a 20 MHz crystal is connected
from this pin to OSCi. This output is not suitable for driving other devices. For clock
oscillator operation, this pin must be left unconnected.
21
OSCi
Oscillator Master Clock (Input). For crystal operation, a 20 MHz crystal is connected
from this pin to OSCo. For clock oscillator operation, this pin must be connected to a
clock source.
22
IC
23
GND
24
APP_SEL1
25
VDD
26
OUT_SEL2
Output Selection 2 (Input). This input selects the signals on the combined output clock
and frame pulse pins, see Table 3 on page 19.
27
OUT_SEL1
Output Selection 1 (Input). This input combined with OUT_SEL0 selects the signals on
the combined output clock pin C6/8.4/34/44o, see Table 3 on page 19.
28
OUT_SEL0
Output Selection 0 (Input). See OUT_SEL1 description.
29
AVDD
30
Internal Connection. Leave unconnected.
Ground. 0 V
Application Selection 1 (Input). This input combined with APP_SEL0 selects the
application that the ZL30105 is optimized for, see Table 1 on page 18.
Positive Supply Voltage. +3.3 VDC nominal
Positive Analog Supply Voltage. +3.3 VDC nominal
C6/8.4/34/44o Clock 6.312 MHz, 8.448 MHz, 34.368 MHz or 44.736 MHz (Output). This output is used
in DS2, E2, E3 or DS3 applications. The output frequency is selected via the OUT_SEL1
and OUT_SEL0 pins, see Table 3 on page 19.
31
C3o
Clock 3.088 MHz (Output). This output is used in DS1 applications.
32
C1.5o
Clock 1.544 MHz (Output). This output is used in DS1 applications.
This clock output pad includes a Schmitt input which serves as a PLL feedback path;
proper transmission-line termination should be applied to maintain reflections below
Schmitt trigger levels.
33
AGND
Analog Ground. 0 V
34
AGND
Analog Ground. 0 V
35
AVCORE
Positive Analog Supply Voltage. +1.8 VDC nominal
36
AVDD
Positive Analog Supply Voltage. +3.3 VDC nominal
37
AVDD
Positive Analog Supply Voltage. +3.3 VDC nominal
38
F2ko
Multi Frame Pulse (Output). This is a 2 kHz 51 ns active high framing pulse, which
marks the beginning of a multi frame.
39
C19o
Clock 19.44 MHz (Output). This output is used in SDH applications.
40
AGND
Analog Ground. 0 V
41
AGND
Analog Ground. 0 V
7
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Pin #
Name
Description
42
C4/C65o
Clock 4.096 MHz or 65.536 MHz (Output). This output is used for ST-BUS operation at
2.048 Mbit/s, 4.096 Mbit/s or 65.536 MHz (ST-BUS 65.536 Mbit/s). The output frequency
is selected via the OUT_SEL2 pin, see Table 3 on page 19.
43
C8/C32o
Clock 8.192 MHz or 32.768 MHz (Output). This output is used for ST-BUS and GCI
operation at 8.192 Mb/s or for operation with a 32.768 MHz clock. The output frequency
is selected via the OUT_SEL2 pin, see Table 3 on page 19.
In C8 mode, this clock output pad uses an included Schmitt input as a PLL feedback
path; proper transmission-line termination should be applied to maintain reflections below
Schmitt trigger levels.
44
AVDD
Positive Analog Supply Voltage. +3.3 VDC nominal
45
AVDD
Positive Analog Supply Voltage. +3.3 VDC nominal
46
C2o
Clock 2.048 MHz (Output). This output is used for standard E1 interface timing and for
ST-BUS operation at 2.048 Mbit/s.
This clock output pad includes a Schmitt input which serves as a PLL feedback path;
proper transmission-line termination should be applied to maintain reflections below
Schmitt trigger levels.
47
C16o
Clock 16.384 MHz (Output). This output is used for ST-BUS operation with a
16.384 MHz clock.
This clock output pad includes a Schmitt input which serves as a PLL feedback path;
proper transmission-line termination should be applied to maintain reflections below
Schmitt trigger levels.
48
F8/F32o
Frame Pulse (Output). This is an 8 kHz 122 ns active high framing pulse or it is an 8 kHz
31 ns active high framing pulse, which marks the beginning of a frame. The pulse width is
selected via the OUT_SEL2 pin, see Table 3 on page 19.
49
F4/F65o
Frame Pulse ST-BUS 2.048 Mbit/s or ST-BUS at 65.536 MHz clock (Output). This
output is an 8 kHz 244 ns active low framing pulse which marks the beginning of an
ST-BUS frame. This is typically used for ST-BUS operation at 2.048 Mbit/s and
4.096 Mbit/s. Or this output is an 8 kHz 15 ns active low framing pulse, typically used for
ST-BUS operation with a clock rate of 65.536 MHz. The pulse width is selected via the
OUT_SEL2 pin, see Table 3 on page 19.
50
F16o
Frame Pulse ST-BUS 8.192 Mbit/s (Output). This is an 8 kHz 61 ns active low framing
pulse, which marks the beginning of an ST-BUS frame. This is typically used for ST-BUS
operation at 8.192 Mbit/s.
51
AGND
52
IC
53
REF_SEL0
Reference Select 0 (Input/Output). In the manual mode of operation, REF_SEL0 is an
input. As an input REF_SEL0 combined with REF_SEL1 selects the reference input that
is used for synchronization, see Table 6 on page 22.
In the Automatic mode of operation, REFSEL0 is an output indicating which of the input
references is the being selected. This pin is internally pulled down to GND.
54
REF_SEL1
Reference Select 1 (Input/Output). See REF_SEL0 pin description.
55
REF0
Analog Ground. 0 V
Internal Connection. Connect this pin to ground.
Reference (Input). This is one of three (REF0, REF1 and REF2) input reference sources
used for synchronization. One of seven possible frequencies may be used: 2 kHz, 8 kHz,
1.544 MHz, 2.048 MHz, 8.192 MHz, 16.384 MHz or 19.44 MHz. This pin is internally
pulled down to GND.
8
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Pin #
Name
Description
56
REF1
Reference (Input). See REF0 pin description.
57
REF2
Reference (Input). See REF0 pin description.
58
REF2_SYNC
REF2 Synchronization Frame Pulse (Input). This is the 2 kHz or 8 kHz (multi) frame
pulse synchronization input associated with the REF2 reference. While the PLL is locked
to the REF2 input reference the output (multi) frame pulses are synchronized to this
input. This pin is internally pulled down to GND.
59
SEC_MSTR
Secondary Master Mode Selection (Input). A logic low at this pin selects the Primary
Master mode of operation with 1.8 Hz or 3.6 Hz DPLL loop filter bandwidth. A logic high
selects Secondary Master mode which forces the PLL to clear its TIE corrector circuit and
lock to the selected reference using a high bandwidth loop filter and a phase slope
limiting of 9.5 ms/s.
60
APP_SEL0
Application Selection (Input). See APP_SEL1 pin description.
61
VDD
62
IC
63
TIE_CLR
64
FASTLOCK
Positive Supply Voltage. +3.3 VDC nominal
Internal Connection. Connect to GND.
TIE Circuit Reset (Input). A logic low at this input resets the Time Interval Error (TIE)
correction circuit resulting in a realignment of input phase with output phase.
Fast Lock (Input). Set temporarily high to allow the ZL30105 to quickly lock to the input
reference (one second locking time).
9
Zarlink Semiconductor Inc.
ZL30105
2.0
Data Sheet
Functional Description
The ZL30105 is an SDH/PDH Synchronizer for Redundant System Clocks, providing timing and synchronization
signals to interface circuits for the following types of primary rate digital transmission links, see Table 1:
•
DS1 compliant with ANSI T1.403 and Telcordia GR-1244-CORE Stratum 4/4E
•
E1 compliant with ITU-T G.703 and ETSI ETS 300 011
•
PDH compliant with Telcordia GR-1244-CORE Stratum 3
•
SDH compliant with ITU-T G.813 option 1 and Telcordia GR-253-CORE
Figure 1 is a functional block diagram of the ZL30105 which is described in the following sections.
2.1
Reference Select Multiplexer (MUX)
The ZL30105 accepts three simultaneous reference input signals and operates on their rising edges. One of them,
the primary reference (REF0), the secondary reference (REF1) or the tertiary reference (REF2) signal is selected
as input to the TIE Corrector Circuit based on the Reference Selection (REF_SEL1:0) inputs.
The use of the combined REF2 and REF2_SYNC inputs allows for a very accurate phase alignment of the output
frame pulses to the 2 kHz or 8 kHz (multi) frame pulse supplied to the REF2_SYNC input. This feature supports the
implementation of Primary and Secondary Master system clocks in AdvancedTCA or H.110 systems.
2.2
Reference Monitor
The input references are monitored by three independent reference monitor blocks, one for each reference. The
block diagram of a single reference monitor is shown in Figure 3. For each reference clock, the frequency is
detected and the clock is continuously monitored for three independent criteria that indicate abnormal behavior of
the reference signal, for example; long term drift from its nominal frequency or excessive jitter. To ensure proper
operation of the reference monitor circuit, the minimum input pulse width restriction of 15 nsec must be
observed.
•
Reference Frequency Detector (RFD): This detector determines whether the frequency of the reference
clock is 2 kHz, 8 kHz, 1.544 MHz, 2.048 MHz 8.192 MHz, 16.384 MHz or 19.44 MHz and provides this
information to the various monitor circuits and the phase detector circuit of the DPLL.
•
Precise Frequency Monitor (PFM): This circuit determines whether the frequency of the reference clock
is within the selected accuracy range, see Table 1.
•
Coarse Frequency Monitor (CFM): This circuit monitors the reference frequency over intervals of
approximately 30 µs to quickly detect large frequency changes.
•
Single Cycle Monitor (SCM): This detector checks the period of a single clock cycle to detect large
phase hits or the complete loss of the clock.
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
REF0 /
REF1 /
REF2
REF_FAIL0 /
REF_FAIL1 /
REF_FAIL2
OR
Reference Frequency
Detector
Precise Frequency
Monitor
OR
Coarse Frequency
Monitor
Reference
select
state machine
REF_SEL1:0
REF_DIS Mode select
state machine
HOLDOVER
REF_OOR
dis/requalify
timer
Single Cycle
Monitor
OR
REF_OOR = reference out of range.
REF_DIS= reference disrupted.
Both are internal signals.
Figure 3 - Reference Monitor Circuit
Exceeding the thresholds of any of the monitors forces the corresponding REF_FAIL pin to go high. The single
cycle and coarse frequency failure flags force the DPLL into Holdover mode and feed a timer that disqualifies the
reference input signal when the failures are present for more than 2.5 s. The single cycle and coarse frequency
failures must be absent for 10 s to let the timer re-qualify the input reference signal as valid. Multiple failures of less
than 2.5 s each have an accumulative effect and will disqualify the reference eventually. This is illustrated in Figure
4 where REF0 experiences disruptions while REF1 is stable.
SCM or CFM failure
SCM or CFM failure
REF0
dis/requalify
timer on REF0
2.5 s
10 s
REF_OOR0
(internal signal)
REF_FAIL0
HOLDOVER
REF_SEL
REF0
REF1
REF0
Figure 4 - Behaviour of the Dis/Re-qualify Timer
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Zarlink Semiconductor Inc.
REF1
ZL30105
Data Sheet
When the incoming signal returns to normal (REF_FAIL=0), the DPLL returns to Normal mode with the output
signal locked to the input signal. Each of the monitors has a build-in hysteresis to prevent flickering of the
REF_FAIL status pin at the threshold boundaries. The precise frequency monitor and the timer do not affect the
mode (Holdover/Normal) of the DPLL.
If the device is set to Automatic mode (MODE_SEL1:0=11), then the state machine does not immediately switch to
another reference. If the single cycle and/or coarse frequency failures persist for more than 2.5 s or the precise
frequency monitor detects a failure, then the state machine will switch to another valid reference if that is available.
If there no other reference available, it stays in Holdover mode.
The precise frequency monitor’s failure thresholds are selected with the APP_SEL pins based on the ZL30105
applications, see Table 1. Figure 5, Figure 6 and Figure 7 show the out of range limits for various master clock
accuracies. It will take the precise frequency monitor up to 10 s to qualify or disqualify the input reference.
C20 Clock Accuracy
Out of Range
C20
0 ppm
In Range
-83
-64
0
64
83
Out of Range
C20
+32 ppm
In Range
-51
96
32
-32
115
Out of Range
C20
-32 ppm
In Range
-115
-96
-100
-32
-75
-50
-25
32
0
51
25
50
100
75
Frequency offset [ppm]
C20: 20 MHz master oscillator clock
Figure 5 - DS1 Out-of-Range Thresholds for APP_SEL1:0=00
C20 Clock Accuracy
Out of Range
C20
0 ppm
In Range
-130 -100
0
100
130
C20
Out of Range
+50 ppm
In Range
-80 -50
150 180
50
Out of Range
C20
-50 ppm
In Range
-180 -150
-200
C20: 20 MHz master oscillator clock
-150
-100
-50
-50
50
0
50
80
100
150
200
Frequency offset [ppm]
Figure 6 - E1 Out-of-Range Thresholds for APP_SEL=01
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
C20 Clock Accuracy
Out of Range
C20
0 ppm
In Range
-12 -9.2
0
9.2 12
Out of Range
C20
+4.6 ppm
In Range
-7.4 -4.6
13.8 16.6
4.6
Out of Range
C20
In Range
-4.6 ppm
-16.6 -13.8
-15
-4.6
-10
-5
4.6
0
5
7.4
10
15
Frequency offset [ppm]
C20: 20 MHz master oscillator clock
Figure 7 - Out-of-Range Thresholds for APP_SEL=10 and APP_SEL=11
In addition to the monitoring of the REF2 reference signal the companion REF2_SYNC input signal is also
monitored for failure (see Figure 8).
Sync Ratio Monitor (SRM): This monitor detects if the REF2_SYNC signal is a 2 kHz or an 8 kHz signal. It also
checks the number of REF2 reference clock cycles in a single REF2_SYNC frame pulse period to determine the
integrity of the REF2_SYNC signal, for example there must be exactly 256 clock cycles of a 2.048 MHz REF2
reference clock in a single REF2_SYNC 8 kHz frame pulse period to validate the REF2_SYNC signal. If the REF2
and REF2_SYNC inputs are selected for synchronization and the Sync Ratio Monitor detects a failure, the DPLL
will abandon the mechanism of aligning the output frame pulse to the REF2_SYNC pulse. Instead only the REF2
reference will be used for synchronization.
REF2_SYNC
REF2
REF2
frequency
SYNC
Reference
Monitor
Circuit
to DPLL
Figure 8 - REF2_SYNC Reference Monitor
2.3
Time Interval Error (TIE) Corrector Circuit
The TIE Circuit eliminates phase transients on the output clock that may occur during reference switching or the
recovery from Holdover mode to Normal mode.
On recovery from Holdover mode (dependent on the HMS pin) or when switching to another reference input, the
TIE corrector circuit measures the phase delay between the current phase (feedback signal) and the phase of the
selected reference signal. This delay value is stored in the TIE corrector circuit. This circuit creates a new virtual
reference signal that is at the same phase position as the feedback signal. By using the virtual reference, the PLL
minimizes the phase transient it experiences when it recovers from Holdover mode.
13
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
The delay value can be reset by setting the TIE Corrector Circuit Clear pin (TIE_CLR) low for at least 15 ns. This
results in a phase alignment between the input reference signal and the output clocks and frame pulses as shown
in Figure 27. The speed of the phase alignment correction is limited by the selected loop filter bandwidth and the
phase slope limit (see Table 2). Convergence is always in the direction of least phase travel. TIE_CLR can be kept
low continuously; in that case the output clocks will always align with the selected input reference. This is illustrated
in Figure 9.
TIE_CLR = 1
TIE_CLR = 0
locked to REF0
locked to REF0
REF0
REF0
REF1
REF1
Output
Clock
Output
Clock
locked to REF1
locked to REF1
REF0
REF0
REF1
REF1
Output
Clock
Output
Clock
Figure 9 - Timing Diagram of Hitless Reference Switching
The Hitless Mode Switching (HMS) pin enables phase hitless returns from Freerun and Holdover modes to Normal
mode in a single reference operation. A logic low at the HMS input disables the TIE circuit updating the delay value
thereby forcing the output of the PLL to gradually move back to the original point before it went into Holdover mode.
(see Figure 10). This prevents accumulation of phase in network elements. A logic high (HMS=1) enables the TIE
circuit to update its delay value thereby preventing a large output phase movement after return to Normal mode.
This causes accumulation of phase in network elements. In both cases the PLL’s output can be aligned with the
input reference by setting TIE_CLR low. Regardless of the HMS pin state, reference switching in the ZL30105 is
always hitless unless TIE_CLR is kept low continuously.
14
Zarlink Semiconductor Inc.
ZL30105
HMS = 0
Data Sheet
HMS = 1
Normal mode
Normal mode
REF
REF
Output
Clock
Output
Clock
Phase drift in Holdover mode
Phase drift in Holdover mode
REF
REF
Output
Clock
Output
Clock
Return to Normal mode
Return to Normal mode
REF
REF
Output
Clock
Output
Clock
TIE_CLR=0
TIE_CLR=0
REF
REF
Output
Clock
Output
Clock
Figure 10 - Timing Diagram of Hitless Mode Switching
Examples:
HMS=1: When ten Normal to Holdover to Normal mode transitions occur and in each case the Holdover mode was
entered for 2 seconds then the accumulated phase change (MTIE) could be as large as 330 ns.
-
Phaseholdover_drift = 0.01 ppm x 2 s = 20 ns
-
Phasemode_change = 0 ns + 13 ns = 13 ns
-
Phase10 changes = 10 x (200 ns + 13 ns) = 330 ns
15
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
where:
-
0.01 ppm is the accuracy of the Holdover mode
-
0 ns is the maximum phase discontinuity in the transition from the Normal mode to the Holdover mode
-
13 ns is the maximum phase discontinuity in the transition from the Holdover mode to the Normal mode
when a new TIE corrector value is calculated
HMS=0: When the same ten Normal to Holdover to Normal mode changes occur and in each case Holdover mode
was entered for 2 seconds, then the overall MTIE would be 20 ns. As the delay value for the TIE corrector circuit is
not updated, there is no 13 ns measurement error at this point. The phase can still drift for 20 ns when the PLL is in
Holdover mode but when the PLL enters Normal mode again, the phase moves back to the original point so the
phase is not accumulated.
2.4
Digital Phase Lock Loop (DPLL)
The DPLL of the ZL30105 consists of a phase detector, a limiter, a loop filter and a digitally controlled oscillator as
shown in Figure 11. The data path from the phase detector to the limiter is tapped and routed to the lock indicator
that provides a lock indication which is output at the LOCK pin.
Lock
Detector
Virtual Reference
from
TIE Corrector Circuit
Phase
Detector
Limiter
Loop Filter
Digitally
Controlled
Oscillator
LOCK
DPLL Reference to
Frequency Synthesizer
REF2_SYNC
frame pulse
State Select from
Control State Machine
Feedback signal from
Frequency Select MUX
feedback frame pulse; F8o or F2ko
Figure 11 - DPLL Block Diagram
Phase Detector - the phase detector compares the virtual reference signal from the TIE corrector circuit with the
feedback signal and provides an error signal corresponding to the phase difference between the two. This error
signal is passed to the limiter circuit.
Limiter - the limiter receives the error signal from the phase detector and ensures that the DPLL responds to all
input transient conditions with a maximum output phase slope compliant with the applicable standards. The phase
slope limit is dependent on the APP_SEL1:0 and SEC_MSTR pins and is listed in Table 2.
Loop Filter - the loop filter is similar to a first order low pass filter with a bandwidth of 1.8 Hz or 3.6 Hz, suitable to
provide Primary Master timing. When Secondary Master mode is selected (SEC_MSTR=1), the filter bandwidth is
set to 922 Hz. For stability reasons, the loop filter bandwidth for 2 kHz and 8 kHz reference inputs is limited to a
maximum of 14 Hz and 58 Hz respectively.
16
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Digitally Controlled Oscillator (DCO) - the DCO receives the limited and filtered signal from the Loop Filter, and
based on its value, generates a corresponding digital output signal. The synchronization method of the DCO is
dependent on the state of the ZL30105.
In Normal Mode, the DCO provides an output signal which is frequency and phase locked to the selected input
reference signal.
In Holdover Mode, the DCO is free running at a frequency equal to the frequency that the DCO was generating in
Normal Mode. The frequency in Holdover mode is calculated from frequency samples stored 26 ms to 52 ms before
the ZL30105 entered Holdover mode. This ensures that the coarse frequency monitor and the single cycle monitor
have time to disqualify a bad reference before it corrupts the holdover frequency.
In Freerun Mode, the DCO is free running with an accuracy equal to the accuracy of the OSCi 20 MHz source.
Lock Indicator - the lock detector monitors if the output value of the phase detector is within the
phase-lock-window for a certain time. The selected phase-lock-window guarantees the stable operation of the
LOCK pin with maximum network jitter and wander on the reference input. If the DPLL goes into Holdover mode
(auto or manual), the LOCK pin will initially stay high for 1 s in Primary Master mode. In Secondary Master mode,
LOCK remains high for 0.1 s. If at that point the DPLL is still in holdover mode, the LOCK pin will go low;
subsequently the LOCK pin will not return high for at least the full lock-time duration. In Freerun mode the LOCK pin
will go low immediately.
2.5
Frequency Synthesizers
The output of the DCO is used by the frequency synthesizers to generate the output clocks and frame pulses which
are synchronized to one of three reference inputs (REF0, REF1 or REF2). The frequency synthesizer uses digital
techniques to generate output clocks and advanced noise shaping techniques to minimize the output jitter. The
clock and frame pulse outputs have limited driving capability and should be buffered when driving high capacitance
loads.
2.6
State Machine
As shown in Figure 1, the state machine controls the TIE Corrector Circuit and the DPLL. The control of the
ZL30105 is based on the inputs MODE_SEL1:0, REF_SEL1:0 and HMS.
2.7
Master Clock
The ZL30105 can use either a clock or crystal as the master timing source. For recommended master timing
circuits, see the Applications - Master Clock section.
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Zarlink Semiconductor Inc.
ZL30105
3.0
Control and Modes of Operation
3.1
Application Selection
Data Sheet
APP_SEL
Application
Applicable Standard
Out Of Range Limits
00
DS1
ANSI T1.403
Telcordia GR-1244-CORE Stratum 4/4E
64 - 83 ppm
01
E1
ITU-T G.703
ETSI ETS 300 011
100 - 130 ppm
10
PDH Stratum 3
Telcordia GR-1244-CORE Stratum 3
9.2 - 12 ppm
11
SDH
ITU-T G.813 Option 1
Telcordia GR-253-CORE
9.2 - 12 ppm
Table 1 - Application Selection and the Out of Range Limits
3.2
Loop Filter and Limiter Selection
The loop filter and limiter settings are selected through the APP_SEL and SEC_MSTR pins, see Table 2. The
maximum loop filter bandwidth is also dependent on the frequency of the currently selected reference (REF0/1/2).
APP_SEL
SEC_MSTR
Detected REF Frequency
Loop Filter Bandwidth
Phase Slope
Limiting
00, 01, 10
0
any
1.8 Hz
61 µ/s
11
0
any
3.6 Hz
7.5 µ/s
00, 01, 10, 11
1
2 kHz
14 Hz
9.5 ms /s
8 kHz
58 Hz
9.5 ms /s
1.544 MHz, 2.048 MHz,
8.192 MHz, 16.384 MHz,
19.44 MHz
922 Hz
9.5 ms /s
Table 2 - Loop Filter and Limiter Settings
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Zarlink Semiconductor Inc.
ZL30105
3.3
Data Sheet
Output Clock and Frame Pulse Selection
The output of the DCO is used by the frequency synthesizers to generate the output clocks and frame pulses which
are synchronized to one of three reference inputs (REF0, REF1 or REF2). These signals are available in two
groups controlled by the OUT_SEL2:0 pins, see Table 3.
OUT_SEL2
Generated Clocks
Generated Frame Pulses
0
C2o, C4o, C8o, C16o
F4o, F8o, F16o
1
C2o, C16o, C32, C65o
F16o, F32o, F65o
OUT_SEL1:0
00
C6o
01
C8.4o
10
C34o
11
C44o
Table 3 - Clock and Frame Pulse Selection with OUT_SEL Pin
3.4
Modes of Operation
The ZL30105 has three possible manual modes of operation; Normal, Holdover and Freerun. These modes are
selected with mode select pins MODE_SEL1 and MODE_SEL0 as is shown in Table 4. Transitioning from one
mode to the other is controlled by an external controller. The ZL30105 can be configured to automatically select a
valid input reference under control of its internal state machine by setting MODE_SEL1:0 = 11. In this mode of
operation, a state machine controls selection of references (REF0 or REF1) used for synchronization.
MODE_SEL1
MODE_SEL0
Mode
0
0
Normal (with automatic Holdover)
0
1
Holdover
1
0
Freerun
1
1
Automatic
(Normal with automatic Holdover and
automatic reference switching)
Table 4 - Operating Modes
3.4.1
Freerun Mode
Freerun mode is typically used when an independent clock source is required, or immediately following system
power-up before network synchronization is achieved.
In Freerun mode, the ZL30105 provides timing and synchronization signals which are based on the master clock
frequency (supplied to OSCi pin) only, and are not synchronized to the reference input signals.
The accuracy of the output clock is equal to the accuracy of the master clock (OSCi). So if a ±32 ppm output clock
is required, the master clock must also be ±32 ppm. See Applications - Section 5.2, “Master Clock“.
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Zarlink Semiconductor Inc.
ZL30105
3.4.2
Data Sheet
Holdover Mode
Holdover Mode is typically used for short durations while network synchronization is temporarily disrupted.
In Holdover Mode, the ZL30105 provides timing and synchronization signals, which are not locked to an external
reference signal, but are based on storage techniques. The storage value is determined while the device is in
Normal Mode and locked to an external reference signal.
When in Normal Mode, and locked to the input reference signal, a numerical value corresponding to the ZL30105
output reference frequency is stored alternately in two memory locations every 26 ms. When the device is switched
into Holdover Mode, the value in memory from between 26 ms and 52 ms is used to set the output frequency of the
device. The frequency accuracy of Holdover Mode is 0.01 ppm.
Two factors affect the accuracy of Holdover mode. One is drift on the master clock while in Holdover mode, drift on
the master clock directly affects the Holdover mode accuracy. Note that the absolute master clock (OSCi) accuracy
does not affect Holdover accuracy, only the change in OSCi accuracy while in Holdover. For example, a ±32 ppm
master clock may have a temperature coefficient of ±0.1 ppm per °C. So a ±10 °C change in temperature, while the
ZL30105 is in Holdover mode may result in an additional offset (over the 0.01 ppm) in frequency accuracy of
±1 ppm. Which is much greater than the 0.01 ppm of the ZL30105. The other factor affecting the accuracy is large
jitter on the reference input prior to the mode switch.
3.4.3
Normal Mode
Normal mode is typically used when a system clock source, synchronized to the network is required. In Normal
mode, the ZL30105 provides timing (C1.5o, C2o, C4o, C8o, C16o, C19o, C32 and C65o) and frame
synchronization (F2ko, F4o, F8o, F16o, F32o and F65o) signals, which are synchronized to one of three reference
inputs (REF0, REF1 or REF2). The input reference signal may have a nominal frequency of 2 kHz, 8 kHz,
1.544 MHz, 2.048 MHz, 8.192 MHz, 16.384 MHz or 19.44 MHz. The frequency of the reference inputs are
automatically detected by the reference monitors.
When the ZL30105 comes out of RESET while Normal mode is selected by its MODE_SEL pins then it will initially
go into Holdover mode and generate clocks with the accuracy of its freerunning local oscillator (see Figure 12). If
the ZL30105 determines that its selected reference is disrupted (see Figure 3), it will remain in Holdover until the
selected reference is no longer disrupted or the external controller selects another reference that is not disrupted. If
the ZL30105 determines that its selected reference is not disrupted (see Figure 3) then the state machine will cause
the DPLL to recover from Holdover via one of two paths depending on the logic level at the HMS pin. If HMS=0 then
the ZL30105 will transition directly to Normal mode and it will align its output signals with its selected input
reference (see Figure 10). If HMS=1 then the ZL30105 will transition to Normal mode via the TIE correction state
and the phase difference between the output signals and the selected input reference will be maintained.
When the ZL30105 is operating in Normal mode, if it determines that its selected reference is disrupted (Figure 3)
then its state machine will cause it to automatically go to Holdover mode. When the ZL30105 determines that its
selected reference is not disrupted then the state machine will cause the DPLL to recover from Holdover via one of
two paths depending on the logic level at the HMS pin (see Figure 12). If HMS=0 then the ZL30105 will transition
directly to Normal mode and it will align its output signals with its input reference (see Figure 10). If HMS=1 then the
ZL30105 will transition to Normal mode via the TIE correction state and the phase difference between the output
signals and the input reference will be maintained.
If the reference selection changes because the value of the REF_SEL1:0 pins changes or because the reference
selection state machine selected a different reference input, the ZL30105 goes into Holdover mode and returns to
Normal mode through the TIE correction state regardless of the logic value on HMS pin.
ZL30105 provides a fast lock pin (FASTLOCK), which, when set high enables the PLL to lock to an incoming
reference within approximately 1 s.
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Normal
(HOLDOVER=0)
REF_CH=1
REF_DIS=0 and
REF_CH=0 and
HMS=0
RST
REF_DIS=0
REF_DIS=1
REF_DIS=1
TIE Correction
(HOLDOVER=1)
Holdover
(HOLDOVER=1)
(REF_DIS=0 and HMS=1) or
REF_CH=1
REF_DIS=1: Current selected reference disrupted (see Figure 3). REF_DIS is an internal signal.
REF_CH= 1: Reference change, a transition in the reference selection (see Figure 14) or a change in the
REF_SEL pins. REF_CH is an internal signal.
Figure 12 - Mode Switching in Normal Mode
3.4.4
Automatic Mode
The Automatic mode combines the functionality of the Normal mode (automatic Holdover) with automatic reference
switching. The automatic reference switching is described in more detail in section 3.5.2, “Automatic Reference
Switching“.
3.5
3.5.1
Reference Switching
Manual Reference Switching
In the manual modes of operation (MODE_SEL1:0 ≠ 11) the active reference input (REF0, REF1 or REF2) is
selected by the REF_SEL1 and REF_SEL0 pins as shown in Table 5. When the logic value of the REF_SEL pins is
changed when the DPLL is in Normal mode, the ZL30105 will perform a hitless reference switch.
REF_SEL1
REF_SEL0
Input Reference Selected
0
0
REF0
0
1
REF1
1
0
REF2
1
1
REF2
Table 5 - Manual Reference Selection
When the REF_SEL inputs are used in Normal mode to force a change from the currently selected reference to
another reference, the action of the LOCK output will depend on the relative frequency and phase offset of the old
and new references. Where the new reference has enough frequency offset and/or TIE-corrected phase offset to
force the output outside the phase-lock-window, the LOCK output will de-assert, the lock-qualify timer is reset, and
LOCK will stay de-asserted for the full lock-time duration. Where the new reference is close enough in frequency
and TIE-corrected phase for the output to stay within the phase-lock-window, the LOCK output will remain asserted
through the reference-switch process.
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Zarlink Semiconductor Inc.
ZL30105
REF_SEL
REF0
Data Sheet
REF1
LOCK
Lock Time
Note: LOCK pin behaviour depends on phase and frequency offset of REF1.
Figure 13 - Reference Switching in Normal Mode
3.5.2
Automatic Reference Switching
In the automatic mode of operation (MODE_SEL1:0 = 11), the ZL30105 automatically selects a reference input that
is not out-of-range (REF_OOR=0, see Figure 3). The state machine can only select REF0 or REF1; REF2 cannot
be selected in the Automatic mode (see Figure 14).
If the current reference (REF0 or REF1) used for synchronization fails, the state machine will switch to the other
reference. If both references fail then the ZL30105 enters the Holdover mode without switching to another
reference. When the ZL30105 comes out of reset or when REF2 is the current reference when the ZL30105 is put
in the Automatic mode, then REF0 has priority over REF1. Otherwise there is no preference for REF0 or REF1
which is referred to as non-revertive reference selection.
RST && REF_OOR0=0
RST && REF_OOR0=1 && REF_OOR1=0
REF_OOR0=0 &&
REF_OOR1=1
REF0
Reference
REF1
Reference
REF_OOR0=1 &&
REF_OOR1=0
REF_OOR0=0
REF_OOR0=1 && REF_OOR1=0
REF2
Reference
REF_OOR = reference out of range, see Figure 3.
This is an internal signal.
Figure 14 - Reference Selection in Automatic Mode (MODE_SEL=11)
In the automatic mode of operation, both pins REF_SEL1 and REF_SEL0 are configured as outputs. The logic level
on the REF_SEL0 output indicates the current input reference being selected for synchronization (see Table 6).
REF_SEL1
(output pin)
REF_SEL0
(output pin)
Input Reference
0
0
REF0
0
1
REF1
Table 6 - The Reference Selection Pins in the Automatic Mode (MODE_SEL=11)
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
The mode selection state machine behaves differently in Automatic mode in that when both reference REF0 and
reference REF1 are out of range (REF_OOR=1), the state machine will select the Holdover state. In Normal mode
the reference out of range (REF_OOR) status is ignored by the state machine. This is illustrated in Figure 15.
Normal
(HOLDOVER=0)
REF_CH=1
REF_DIS=0 and REF_OOR=0
and REF_CH=0 and HMS=0
REF_DIS=0
and REF_OOR=0
RST
REF_DIS=1
or REF_OOR=1
TIE Correction
(HOLDOVER=1)
Holdover
(HOLDOVER=1)
(REF_DIS=0 and REF_OOR=0 and HMS=1)
or REF_CH=1
REF_DIS=1: Current selected reference disrupted (see Figure 3). REF_DIS is an internal signal.
REF_OOR=1: Current selected reference out of range (see Figure 3). REF_OOR is an internal signal.
REF_CH= 1: Reference change, a transition in the reference selection (see Figure 14). REF_CH is an internal signal.
Figure 15 - Mode Switching in Automatic Mode
3.5.2.1
Automatic Reference Switching - Coarse Reference Failure
When the currently-active input reference in Automatic mode fails in a coarse manner, the REF_DIS internal signal
places the device in holdover, with the HOLDOVER pin and the REF_FAIL pin asserted. This can occur through
triggering the Single Cycle Monitor, or the Coarse Frequency Monitor, in the Reference Monitor block. If the
reference does not correct itself within the lock-disqualify duration (1 second) the LOCK pin is de-asserted. If the
reference does not correct itself within the reference-disqualify duration (2.5 seconds) the HOLDOVER pin is
de-asserted and the REF_SEL outputs indicate that the device has switched to the other reference. The LOCK pin
remains de-asserted for the full lock-time duration, regardless of the phase and frequency offset of the old and new
references. Figure 16 illustrates this process.
If the reference corrects itself within the lock-disqualify duration (< 1 second) the HOLDOVER pin is de-asserted,
and the REF_FAIL pin is de-asserted. The LOCK pin remains asserted. No reference switching takes place, and
the REF_SEL outputs indicate that the device has remained locked to the old reference.
If the reference does not correct itself within the lock-disqualify duration (1 second), but does correct itself within the
reference-disqualify duration (< 2.5 seconds) the HOLDOVER pin is de-asserted, the REF_FAIL pin is de-asserted,
and the REF_SEL outputs indicate that the device has remained locked to the old reference. However the LOCK
pin is de-asserted, the lock-qualify timer is reset, and the LOCK pin remains de-asserted for the full lock-time
duration. See 6.2, “Performance Characteristics“ on page 44 for lock-time duration.
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
SCM or CFM failure
REF0
REF_DIS0
(internal signal)
2.5 s
10 s
REF_OOR0
(internal signal)
REF_FAIL0
HOLDOVER
REF_SEL
REF0
REF1
LOCK
Lock Time
1s
Note: this scenario is based on REF1 remaining good throughout the duration.
Figure 16 - Automatic Reference Switching - Coarse Reference Failure
3.5.2.2
Automatic Reference Switching - Reference Frequency Out-of-Range
When the currently-active input reference in Automatic mode fails through a subtle frequency offset, the REF_FAIL
output is asserted as soon as the Precise Frequency Monitor indicates an out-of-range reference (10 to 20
seconds). The HOLDOVER output is briefly asserted (approximately three reference input cycles) and the
REF_SEL outputs indicate that the device has switched to the other reference. Where the new reference is close
enough in frequency and TIE-corrected phase for the output to stay within the phase-lock-window, the LOCK output
will remain asserted through the reference-switch process. Where the new reference has enough frequency offset
and/or TIE-corrected phase offset to force the output outside the phase-lock-window, the LOCK output will
de-assert, the lock-qualify timer is reset, and LOCK will stay de-asserted for the full lock-time duration. Figure 17
illustrates this process.
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Frequency Precision failure
REF0
10 to 20 s
REF_OOR0
(internal signal)
REF_FAIL0
HOLDOVER
REF_SEL
REF0
REF1
LOCK
Lock Time
Note: This scenario is based on REF1 remaining good throughout the duration.
LOCK pin behaviour depends on phase and frequency offset of REF1.
Figure 17 - Automatic Reference Switching - Out-of-Range Reference Failure
3.6
Clock Redundancy Support
In general, clock redundancy implies that the redundant timing card DPLL tracks the output clock and/or frame
pulse of the active timing card DPLL. In case that the active timing card fails, the devices that use the active clock
and/or frame pulse must be able to switch to the redundant clock and/or frame pulse without experiencing
disruptions. Therefore the redundant signals must closely track the active signals. The ZL30105 supports this kind
of clock redundancy in various ways;
•
Lock only to the active clock. The ZL30105 uses the 922 Hz loop filter bandwidth to closely track the active
clock, even in the presence of jitter on the active clock. However the active and redundant frame pulse may
not be aligned.
•
Lock to the active frame pulse. Both the redundant clock and frame pulse will be aligned with the active clock
and frame pulse. However the ZL30105 loop filter bandwidth is limited to 14 Hz (2 kHz active frame pulse) or
58 Hz (8 kHz active frame pulse). Therefore the redundant clock and frame pulse will not track the active
frame pulse as closely in the presence of jitter on the active frame pulse as with a 922 Hz loop filter
bandwidth.
•
Lock to both the active clock and associated frame pulse. The ZL30105 uses the 922 Hz loop filter
bandwidth and thereby track the active clock and frame pulse in the presence of jitter on the active signals. It
will also align the redundant frame pulse with the active frame pulse.
The method of clock redundancy shown in Figure 19 is that the redundant timing card is frequency and phase
locked to the active clock and frame pulse. The redundant card is configured as Secondary Master (SEC_MSTR=1)
and continuously adjusts the phase of its output clocks and frame pulses to match that of the active clock and frame
pulse. In this mode of operation, the bandwidth of the redundant timing card’s DPLL is much larger than that of the
active timing card’s DPLL, 922 Hz versus 1.8 Hz. Therefore the redundant clocks and frame pulses will track the
active clock and frame pulse closely even in the presence of the maximum tolerable input jitter and wander on the
active timing card’s reference input.
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
The method of synchronization using REF2 and REF2_SYNC is enabled as soon as a valid 2 kHz or 8 kHz frame
pulse is detected on the REF2_SYNC input. The REF2_SYNC pulse must be generated from the clock that is
present on the REF2 input. The ZL30105 checks the number of REF2 cycles in the REF2_SYNC period. If this is
not the nominal number of cycles, the REF2_SYNC pulse is considered invalid. For example, if REF2 is a
8.192 MHz clock and REF2_SYNC is a 8 kHz frame pulse, then there must be exactly 1024 REF2 cycles in a
REF2_SYNC period. If a valid REF2_SYNC pulse is detected, the ZL30105 will align the rising edges of the REF2
clock and the corresponding output clock such that the rising edge of the F8o/F32o output frame pulse is aligned
with the frame boundary indicated by the REF2_SYNC signal. The rising edges of the REF2 and the corresponding
output clock that are aligned, are the ones that lag the rising edges of the REF2_SYNC and the F8o pulses
respectively. This is illustrated in Figure 18. Many combinations of the ZL30105 clock and frame pulse outputs can
be used as REF2 and REF2_SYNC inputs. In general, the active low frame pulses F4o, F16o and F65o would be
inverted first before used as a REF2_SYNC input.
REF2_SYNC = 8 kHz
REF2 = C8o
aligned
F8o
C8o
REF2_SYNC = 2 kHz
REF2 = C19o
aligned
F2ko
C19o
Figure 18 - Examples of REF2 & REF2_SYNC to Output Alignment
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Active Timing Card
MODE_SEL1:0=11
REF_SEL1:0=10
SEC_MSTR=0
BITS 0 clock
BITS 1 clock
OSC
REF0
Output Clocks
REF1
ZL30105
REF2
REF2_SYNC
Redundant Frame Sync (optional)
Redundant Clock
Active Clock
Active Frame Sync (optional)
REF2_SYNC
REF2
BITS 0 clock
BITS 1 clock
ZL30105
REF0
Output Clocks
REF1
MODE_SEL1:0=11
REF_SEL1:0=10
SEC_MSTR=0
OSC
Redundant Timing Card
Figure 19 - Clock Redundancy with Two Independent Timing Cards
The following is an example of how active/redundant setup can be configured.
The active timing card is set based on the desired application and is set to:
•
Primary master mode, SEC_MSTR=0
•
Normal Mode, MODE_SEL1:0=00 (forces device to the input reference set at REF_SEL)
•
Automatic mode, MODE_SEL1:0=11 (allows device to auto-switch if reference fails)
The HOLDOVER and REF_FAIL pins help evaluate quality of clocks and quality of redundant clock.
The redundant timing card is set based on desired applications and is set to:
•
Normal (manual) mode, MODE_SEL1:0=00
•
REF2 and REF2_SYNC as the input reference, REF_SEL1=1 (forces redundant device to lock to output
of active card)
•
Secondary master mode, SEC_MSTR=1
The HOLDOVER and REF_FAIL pins help evaluate quality of clocks and quality of redundant clock.
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
When the redundant timing card is switched to becoming the active timing card, the system controller should do the
following:
•
select Primary Master mode, SEC_MSTR=0
•
select Automatic mode, MODE_SEL1:0=11
The new active timing card will automatically select a valid input reference REF0 or REF1. If both input references
are available and valid, then REF0 will be chosen over REF1. If the new active timing card should use the same
input reference (REF0 or REF1) as the old active timing card used before it failed, The system controller should do
the following instead:
•
select Holdover (manual) mode, MODE_SEL1:0=01
•
select Primary Master mode, SEC_MSTR=0
•
select the required reference (REF0 or REF1) as the input reference
•
Normal Mode, MODE_SEL1:0=00 (forces device to the input reference set at REF_SEL)
•
select Automatic mode, MODE_SEL1:0=11
It is recommended to maintain HMS=1 when switching from redundant to active through the Holdover mode, to
eliminate output phase transients.
When the active timing card is switched to becoming the redundant timing card, the system controller should do the
following:
•
select Normal (manual) mode, MODE_SEL1:0=00
•
select Secondary Master mode, SEC_MSTR=1
•
select REF2 and REF2_SYNC as the input reference, REF_SEL1=1
The ZL30105 allows for the switch from Secondary Master mode to Primary Master mode with no frequency or
phase hits on the output clocks. The switch from Primary Master mode to Secondary Master mode may introduce a
phase transient on the output clocks as the TIE correction circuit is disabled to allow the Secondary master device
to track the active clocks closely.
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Zarlink Semiconductor Inc.
ZL30105
4.0
Data Sheet
Measures of Performance
The following are some PLL performance indicators and their corresponding definitions.
4.1
Jitter
Timing jitter is defined as the high frequency variation of the clock edges from their ideal positions in time. Wander
is defined as the low-frequency variation of the clock edges from their ideal positions in time. High and low
frequency variation imply phase oscillation frequencies relative to some demarcation frequency. (Often 10 Hz or
20 Hz for DS1 or E1, higher for SONET/SDH clocks.) Jitter parameters given in this data sheet are total timing jitter
numbers, not cycle-to-cycle jitter.
4.2
Jitter Generation (Intrinsic Jitter)
Jitter generation is the measure of the jitter produced by the PLL and is measured at its output. It is measured by
applying a reference signal with no jitter to the input of the device, and measuring its output jitter. Jitter generation
may also be measured when the device is in a non-synchronizing mode, such as free running or holdover, by
measuring the output jitter of the device. Jitter is usually measured with various bandlimiting filters depending on
the applicable standards.
4.3
Jitter Tolerance
Jitter tolerance is a measure of the ability of a PLL to operate properly (i.e., remain in lock and or regain lock in the
presence of large jitter magnitudes at various jitter frequencies) when jitter is applied to its reference. The applied
jitter magnitude and jitter frequency depends on the applicable standards.
4.4
Jitter Transfer
Jitter transfer or jitter attenuation refers to the magnitude of jitter at the output of a device for a given amount of jitter
at the input of the device. Input jitter is applied at various amplitudes and frequencies, and output jitter is measured
with various filters depending on the applicable standards.
For the Zarlink digital PLLs two internal elements determine the jitter attenuation; the internal low pass loop filter
and the phase slope limiter. The phase slope limiter limits the output phase slope to, for example, 61 µs/s.
Therefore, if the input signal exceeds this rate, such as for very large amplitude low frequency input jitter, the
maximum output phase slope will be limited (i.e., attenuated).
Since intrinsic jitter is always present, jitter attenuation will appear to be lower for small input jitter signals than for
large ones. Consequently, accurate jitter transfer function measurements are usually made with large input jitter
signals (for example 75% of the specified maximum tolerable input jitter).
4.5
Frequency Accuracy
The Frequency accuracy is defined as the absolute accuracy of an output clock signal when it is not locked to an
external reference, but is operating in a free running mode.
4.6
Holdover Accuracy
Holdover accuracy is defined as the absolute accuracy of an output clock signal, when it is not locked to an external
reference signal, but is operating using storage techniques. For the ZL30105, the storage value is determined while
the device is in Normal Mode and locked to an external reference signal.
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Zarlink Semiconductor Inc.
ZL30105
4.7
Data Sheet
Pull-in Range
Also referred to as capture range. This is the input frequency range over which the PLL must be able to pull into
synchronization.
4.8
Lock Range
This is the input frequency range over which the synchronizer must be able to maintain synchronization.
4.9
Phase Slope
Phase slope is measured in seconds per second and is the rate at which a given signal changes phase with respect
to an ideal signal. The given signal is typically the output signal. The ideal signal is of constant frequency and is
nominally equal to the value of the final output signal or final input signal. Another way of specifying the phase slope
is as the fractional change per time unit. For example; a phase slope of 61 µs/s can also be specified as 61 ppm.
4.10
Time Interval Error (TIE)
TIE is the time delay between a given timing signal and an ideal timing signal.
4.11
Maximum Time Interval Error (MTIE)
MTIE is the maximum peak to peak delay between a given timing signal and an ideal timing signal within a
particular observation period.
4.12
Phase Continuity
Phase continuity is the phase difference between a given timing signal and an ideal timing signal at the end of a
particular observation period. Usually, the given timing signal and the ideal timing signal are of the same frequency.
Phase continuity applies to the output of the PLL after a signal disturbance due to a reference switch or a mode
change. The observation period is usually the time from the disturbance, to just after the synchronizer has settled to
a steady state.
4.13
Lock Time
This is the time it takes the PLL to frequency lock to the input signal. Phase lock occurs when the input signal and
output signal are aligned in phase with respect to each other within a certain phase distance (not including jitter).
Lock time is affected by many factors which include:
•
initial input to output phase difference
•
initial input to output frequency difference
•
PLL loop filter bandwidth
•
PLL phase slope limiter
•
in-lock phase distance
The presence of input jitter makes it difficult to define when the PLL is locked as it may not be able to align its output
to the input within the required phase distance, dependent on the PLL bandwidth and the input jitter amplitude and
frequency.
Although a short lock time is desirable, it is not always possible to achieve due to other synchronizer requirements.
For instance, better jitter transfer performance is achieved with a lower frequency loop filter which increases lock
time. And better (smaller) phase slope performance (limiter) results in longer lock times.
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Zarlink Semiconductor Inc.
ZL30105
5.0
Data Sheet
Applications
This section contains ZL30105 application specific details for power supply decoupling, reset operation, clock and
crystal operation.
5.1
Power Supply Decoupling
It is recommended to place a 100 nF decoupling capacitor close to each pair of power and ground pins as
illustrated in Figure 20 to ensure optimal jitter performance.
3.3 V
1.8 V
AV CORE 35
29 AV DD
100 nF
100 nF
33 AGND
AV CORE 14
44 AV DD
100 nF
100 nF
V CORE 12
41 AGND
100 nF
GND 13
45 AV DD
100 nF
V CORE 2
51 AGND
100 nF
GND 1
37 AV DD
100 nF
40 GND
36 AVDD
ZL30105
100 nF
34 GND
25 V DD
100 nF
23 GND
61 V DD
100 nF
1 GND
Figure 20 - Recommended Power Supply Decoupling
5.2
Master Clock
The ZL30105 can use either a clock or crystal as the master timing source. Zarlink application note ZLAN-68 lists a
number of applicable oscillators and crystals that can be used with the ZL30105.
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Zarlink Semiconductor Inc.
ZL30105
5.2.1
Data Sheet
Clock Oscillator
When selecting a clock oscillator, numerous parameters must be considered. This includes absolute frequency,
frequency change over temperature, output rise and fall times, output levels, duty cycle and phase noise.
1
Frequency
20 MHz
2
Tolerance
as required
3
Rise & fall time
< 10 ns
4
Duty cycle
40% to 60%
Table 7 - Typical Clock Oscillator Specification
The output clock should be connected directly (not AC coupled) to the OSCi input of the ZL30105 and the OSCo
output should be left open as shown in Figure 21.
ZL30105
+3.3 V
OSCi
+3.3 V
20 MHz OUT
GND
0.1 µF
OSCo
No Connection
Figure 21 - Clock Oscillator Circuit
5.2.2
Crystal Oscillator
Alternatively, a Crystal Oscillator may be used. A complete oscillator circuit made up of a crystal, resistor and
capacitors is shown in Figure 22.
The accuracy of a crystal oscillator depends on the crystal tolerance as well as the load capacitance tolerance.
Typically, for a 20 MHz crystal specified with a 32 pF load capacitance, each 1 pF change in load capacitance
contributes approximately 9 ppm to the frequency deviation. Consequently, capacitor tolerances and stray
capacitances have a major effect on the accuracy of the oscillator frequency.
The crystal should be a fundamental mode type - not an overtone. The fundamental mode crystal permits a simpler
oscillator circuit with no additional filter components and is less likely to generate spurious responses. A typical
crystal oscillator specification and circuit is shown in Table 8 and Figure 22 respectively.
.
1
Frequency
20 MHz
2
Tolerance
as required
3
Oscillation mode
fundamental
4
Resonance mode
parallel
5
Load capacitance
as required
6
Maximum series resistance
50 Ω
Table 8 - Typical Crystal Oscillator Specification
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Zarlink Semiconductor Inc.
ZL30105
Data Sheet
20 MHz
ZL30105
OSCi
1 MΩ
OSCo
100 Ω
1 µH
The 100 Ω resistor and the 1 µH inductor may improve
stability and are optional.
Figure 22 - Crystal Oscillator Circuit
5.3
Power Up Sequence
The ZL30105 requires that the 3.3 V is not powered after the 1.8 V. This is to prevent the risk of latch-up due to the
presence of parasitic diodes in the IO pads.
Two options are given:
1. Power-up 3.3 V first, 1.8 V later
2. Power up 3.3 V and 1.8 V simultaneously ensuring that the 3.3 V power is never lower than 1.8 V minus a few
hundred millivolts (e.g., by using a schottky diode or controlled slew rate)
5.4
Reset Circuit
A simple power up reset circuit with about a 300 µs reset low time is shown in Figure 23. Resistor RP is for
protection only and limits current into the RST pin during power down conditions. The reset low time is not critical
but should be greater than 300 ns.
ZL30105
+3.3 V
R
10 kΩ
RST
RP
1 kΩ
C
10 nF
Figure 23 - Power-Up Reset Circuit
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Zarlink Semiconductor Inc.
ZL30105
5.5
Data Sheet
Clock Redundancy System Architecture
Carrier-Class Telecommunications Equipment deployed in today’s networks guarantee better than 99.999%
operational availability (equivalent to less than 7 minutes of downtime per year). This high level of uninterrupted
service is achieved by fully redundant architectures with hot swappable cards like an ECTF H.110 or a PICMG
AdvancedTCA™ compliant system. Timing for these types of systems can be generated by the ZL30105 which
supports primary/secondary master timing protection switching.
The architecture shown in Figure 24 and Figure 25 is based on the ZL30105 being deployed on two separate timing
cards; the primary master timing card and the secondary master timing card. In normal operation the primary
master timing card receives synchronization from the network and provides timing for the whole system. The
redundant secondary master timing card is phase locked to the backplane clock and frame pulse through its REF2
and REF2_SYNC inputs. These two designated inputs allow the secondary master timing card to track the primary
master timing card clocks with minimal phase skew. When the primary master timing card fails unexpectedly (this
failure is not related to reference failure) then all switch cards or line cards will detect this failure and they will switch
to the timing supplied by the secondary master timing card. The secondary master timing card will be promoted to
primary master and switch from using the REF2 and REF2_SYNC inputs to one of the REF0 or REF1 inputs.
Backplane
CT_FRAME_B
CT_C8_A
CT_FRAME_A
CT_C8_B
CT_NETREF_2
CT_NETREF_1
ZL30105
REF0
REF1
MT90866
H.110 DX
C8o
REF2
F8o
REF2_SYNC
SEC_MSTR
0
Master/Slave
Control
Primary Master Timing Card
MT90866
H.110 DX
ZL30105
REF0
REF1
C8o
REF2
F8o
REF2_SYNC
SEC_MSTR
1
Master/Slave
Control
Secondary Master Timing Card
Figure 24 - Typical Clocking Architecture of an ECTF H.110 System
34
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Backplane
CLK1B
CLK2A
CLK1A
CLK2B
CLK3A
CLK3B
ZL30105
REF0
REF1
ZL30106
Line Card
PLL
C19o
REF2
F8o
REF2_SYNC
SEC_MSTR
0
Master/Slave
Control
Primary Master Timing Card
ZL30106
Line Card
PLL
ZL30105
REF0
REF1
C19o
REF2
F8o
REF2_SYNC
SEC_MSTR
1
Master/Slave
Control
Secondary Master Timing Card
Figure 25 - Typical Clocking Architecture of a PICMG AdvancedTCA™ System
35
Zarlink Semiconductor Inc.
ZL30105
6.0
Characteristics
6.1
AC and DC Electrical Characteristics
Data Sheet
Absolute Maximum Ratings*
Parameter
Symbol
Min.
Max.
Units
VDD_R
-0.5
4.6
V
VCORE_R
-0.5
2.5
V
1
Supply voltage
2
Core supply voltage
3
Voltage on any digital pin
VPIN
-0.5
6
V
4
Voltage on OSCi and OSCo pin
VOSC
-0.3
VDD + 0.3
V
5
Current on any pin
IPIN
30
mA
6
Storage temperature
TST
125
°C
7
TQFP 64 pin package power dissipation
PPD
8
ESD rating
VESD
-55
mW
2
kV
* Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied.
* Voltages are with respect to ground (GND) unless otherwise stated.
Recommended Operating Conditions*
Characteristics
1
Supply voltage
2
Core supply voltage
3
Operating temperature
Sym.
Min.
Typ.
Max.
Units
VDD
2.97
3.30
3.63
V
VCORE
1.62
1.80
1.97
V
TA
-40
25
85
°C
* Voltages are with respect to ground (GND) unless otherwise stated.
DC Electrical Characteristics*
Characteristics
1
Supply current with: OSCi = 0 V
Sym.
Min.
Max.
Units
IDDS
1
8
mA
Notes
outputs loaded
with 30 pF
2
OSCi = Clock, OUT_SEL=000
IDD
30
50
mA
3
OSCi = Clock, OUT_SEL=111
IDD
45
68
mA
4
Core supply current with: OSCi = 0 V
ICORES
0
25
µA
5
OSCi = Clock
ICORE
14
22
mA
6
Schmitt trigger Low to High threshold
point
Vt+
1.47
1.5
V
7
Schmitt trigger High to Low threshold
point
Vt-
0.89
0.95
V
8
Input leakage current
IIL
-105
105
µA
VI = VDD or 0 V
9
High-level output voltage
VOH
2.4
V
IOH = 10 mA
10
Low-level output voltage
VOL
V
IOL = 10 mA
0.4
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
* Voltages are with respect to ground (GND) unless otherwise stated.
36
Zarlink Semiconductor Inc.
All device inputs are
Schmitt trigger type.
ZL30105
Data Sheet
AC Electrical Characteristics* - Timing Parameter Measurement Voltage Levels (see Figure 26).
Characteristics
Sym.
CMOS
Units
VT
0.5 · VDD
V
1
Threshold Voltage
2
Rise and Fall Threshold Voltage High
VHM
0.7 · VDD
V
3
Rise and Fall Threshold Voltage Low
VLM
0.3 · VDD
V
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
* Voltages are with respect to ground (GND) unless otherwise stated.
Timing Reference Points
V HM
VT
V LM
ALL SIGNALS
tIRF, tORF
tIRF, tORF
Figure 26 - Timing Parameter Measurement Voltage Levels
AC Electrical Characteristics* - Input timing for REF0, REF1 and REF2 references (see Figure 27).
Characteristics
Symbol
Min.
Typ.
Max.
Units
1
2 kHz reference period
tREF2kP
484
500
515
µs
2
8 kHz reference period
tREF8kP
121
125
128
µs
3
1.544 MHz reference period
tREF1.5P
338
648
950
ns
4
2.048 MHz reference period
tREF2P
263
488
712
ns
5
8.192 MHz reference period
tREF8P
63
122
175
ns
6
16.384 MHz reference period
tREF16P
38
61
75
ns
7
19.44 MHz reference period
tREF8kP
38
51
75
ns
8
reference pulse width high or low
tREFW
15
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
* Period Min/Max values are the limits to avoid a single-cycle fault detection. Short-term and long-term average periods must be within
Out-of-Range limits.
37
Zarlink Semiconductor Inc.
ns
ZL30105
Data Sheet
tREF<xx>P
tREFW
tREFW
REF0/1/2
output clock with the
same frequency as
REF
tREF<xx>D
tREF8kD, tREF<xx>_F8D
F8_32o
Figure 27 - REF0/1/2 Input Timing and Input to Output Timing
AC Electrical Characteristics* - Input timing for REF2_SYNC (see Figure 28).
1
Characteristics
REF2_SYNC
frequency
Symbol
REF2_SYNC lead time
2 kHz
2
3
REF2_SYNC lag time
4
5
REF2_SYNC pulse
width high or low
Min.
Max.
Units
tSYNC_LD
0
ns
8 kHz
tSYNC_LD
12
ns
2 kHz
tSYNC_LG
tREFP - 15
ns
tREFP = minimum
period of REF2 clock
8 kHz
tSYNC_LG
tREFP - 28
ns
tREFP = minimum
period of REF2 clock
2 kHz, 8 kHz
tSYNC_W
15
ns
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
* See Figure 18, “Examples of REF2 & REF2_SYNC to Output Alignment” on page 26 for further explanation.
edge used for alignment
tREFP
REF2
tSYNC_LD
tSYNC_LG
REF2_SYNC
tSYNC_W
Note:
REF2 can be 1.544 MHz, 2.048 MHz, 8.192 MHz, 16.384 MHz or 19.44 MHz.
REF2_SYNC can be 2 kHz or 8 kHz.
Figure 28 - REF2_SYNC Timing
38
Zarlink Semiconductor Inc.
Notes
ZL30105
Data Sheet
AC Electrical Characteristics* - Input to output timing for REF0, REF1 and REF2 references when
TIE_CLR = 0 (see Figure 27).
Characteristics
Symbol
Min.
Max.
Units
tREF2kD
0.3
1.0
ns
1
2 kHz reference input to F2ko delay
2
2 kHz reference input to F8/F32o delay
tREF2k_F8D
-27.2
-26.5
ns
3
8 kHz reference input to F8/F32o delay
tREF8kD
-2.0
-0.3
ns
4
1.544 MHz reference input to C1.5o delay
tREF1.5D
-0.9
-0.2
ns
5
1.544 MHz reference input to F8/F32o delay
tREF1.5_F8D
-0.5
0.5
ns
6
2.048 MHz reference input to C2o delay
tREF2D
-1.1
-0.2
ns
7
2.048 MHz reference input to F8/F32o delay
tREF2_F8D
-0.2
0.6
ns
8
8.192 MHz reference input to C8o delay
tREF8D
-1.5
-0.5
ns
9
8.192 MHz reference input to F8/F32o delay
tREF8_F8D
-0.1
1.2
ns
10
16.384 MHz reference input to C16o delay
tREF16D
-1.1
1.9
ns
11
16.384 MHz reference input to F8/F32o delay
tREF16_F8D
29.4
30.3
ns
12
19.44 MHz reference input to C19o delay
tREF19D
0.4
1.0
ns
13
19.44 MHz reference input to F8/F32o delay
tREF19_F8D
-1.7
-1.1
ns
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
39
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
AC Electrical Characteristics* - E1 output timing (see Figure 29).
Characteristics
Sym.
Min.
Max.
Units
1
C2o delay
tC2D
-0.4
0.3
ns
2
C2o pulse width low
tC2L
243.2
244.1
ns
3
F4o pulse width low
tF4L
243.5
244.2
ns
4
F4o delay
tF4D
121.5
122.2
ns
5
C4o pulse width low
tC4L
121.1
122.3
ns
6
C4o delay
tC4D
-0.3
1.1
ns
7
F8o pulse width high
tF8H
121.6
123.2
ns
8
C8o pulse width low
tC8L
60.3
61.3
ns
9
C8o delay
tC8D
-0.4
0.3
ns
10
F16o pulse with low
tF16L
61.1
60.6
ns
11
F16o delay
tF16D
29.9
30.8
ns
12
C16o pulse width low
tC16L
28.7
30.8
ns
13
C16o delay
tC16D
-0.5
1.5
ns
14
F32o pulse width high
tF32H
31.8
30.0
ns
15
C32o pulse width low
tC32L
14.7
15.3
ns
16
C32o delay
tC32D
-0.5
0.5
ns
17
F65o pulse with low
tF65L
15.4
14.8
ns
18
F65o delay
tF65D
7.1
8.0
ns
19
C65o pulse width low
tC65L
7.2
8.1
ns
20
C65o delay
tC65D
-1.0
1.0
ns
21
Output clock and frame pulse rise time
tOR
1.1
2.0
ns
22
Output clock and frame pulse fall time
tOF
1.2
2.3
ns
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
40
Zarlink Semiconductor Inc.
Notes
outputs loaded
with 30 pF
ZL30105
Data Sheet
tF8H
F8o
tC2D
tC2L
C2o
tF4D
tF4L
F4o
tC4D
tC4L
C4o
tC8L
tC8D
C8o
tF16D
tF16L
F16o
tC16L
tC16D
C16o
tF32H
F32o
tC32L
tC32D
C32o
tF65D
tF65L
F65o
tC65D
tC65L
C65o
F32o, C32o, F65o and C65o are drawn on a larger scale than the other waveforms in this diagram.
Figure 29 - E1 Output Timing Referenced to F8/F32o
41
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
AC Electrical Characteristics* - DS1 output timing (see Figure 30).
Characteristics
Sym.
Min.
Max.
Units
1
C1.5o delay
tC1.5D
-0.6
0.6
ns
2
C1.5o pulse width low
tC1.5L
323.1
323.8
ns
3
C3o delay
tC3D
-0.7
0.5
ns
4
C3o pulse width low
tC3L
161.1
162.0
ns
5
Output clock and frame pulse rise time
tOR
1.1
2.0
ns
6
Output clock and frame pulse fall time
tOF
1.2
2.3
ns
Notes
outputs loaded
with 30 pF
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
o
F8_32o
tC1.5D
tC1.5L
C1.5o
tC3D
tC3L
C3o
Figure 30 - DS1 Output Timing Referenced to F8/F32o
AC Electrical Characteristics* - SDH output timing (see Figure 31).
Characteristics
Sym.
Min.
Max.
Units
1
C19o delay
tC19D
-1.0
0.5
ns
2
C19o pulse width low
tC19L
25.0
25.8
ns
3
F2ko delay
tF2kD
25.0
26.6
ns
4
F2ko pulse width high
tF2kH
51.1
51.8
ns
5
Output clock and frame pulse rise time
tOR
1.1
2.0
ns
6
Output clock and frame pulse fall time
tOF
1.2
2.3
ns
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
F8_32o
tC19L
tC19D
C19o
tF2D
tF2kH
F2ko
Figure 31 - SDH Output Timing Referenced to F8/F32o
42
Zarlink Semiconductor Inc.
Notes
outputs loaded
with 30 pF
ZL30105
Data Sheet
AC Electrical Characteristics* - DS2, E2, E3 and DS3 Output Timing (see Figure 32).
Characteristics
Sym.
Min.
Max.
Units
1
C6o delay
tC6D
-0.70
0.70
ns
2
C6o pulse width low
tC6L
78.5
79.3
ns
3
C8.4o delay
tC8.4D
-0.8
0.8
ns
4
C8.4o pulse width low
tC8.4L
58.4
59.1
ns
5
C34o delay
tC34D
-0.5
0.5
ns
6
C34o pulse width low
tC34L
13.5
14.4
ns
7
C44o delay
tC44D
-1.0
0.5
ns
8
C44o pulse width low
tC44L
10.4
11.2
ns
9
Output clock and frame pulse rise time
tOR
1.1
2.0
ns
10
Output clock and frame pulse fall time
tOF
1.2
2.3
ns
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
F8_32o
tC44L
tC44D
C44o
tC34L
tC34D
C34o
tC8.4L
tC8.4D
C8.4o
tC6L
tC6D
C6o
Figure 32 - DS3, E3, E2 and DS2 Output Timing Referenced to F8/F32o
43
Zarlink Semiconductor Inc.
Notes
outputs
loaded with
30 pF
ZL30105
Data Sheet
AC Electrical Characteristics* - OSCi 20MHz Master Clock Input
Characteristics
Min.
Max.
Units
1
Oscillator Tolerance - DS1
-32
+32
ppm
2
Oscillator Tolerance - E1
-50
+50
ppm
3
Oscillator Tolerance - PDH Stratum 3
-4.6
+4.6
ppm
4
Oscillator Tolerance - SDH
-4.6
+4.6
ppm
5
Duty cycle
40
60
%
6
Rise time
10
ns
7
Fall time
10
ns
Notes
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
6.2
Performance Characteristics
Performance Characteristics* - Functional
Characteristics
Min.
Max.
Units
0.01
ppm
Notes
1
Holdover accuracy
2
Holdover stability
0
ppm
Determined by stability of the
20 MHz master clock oscillator
3
Freerun accuracy
0
ppm
Determined by accuracy of the
20 MHz master clock oscillator
Capture range
4
DS1 / E1
-130
+130
ppm
The 20 MHz master clock oscillator
set at 0 ppm
5
PDH Stratum 3 / SDH
-12
+12
ppm
The 20 MHz master clock oscillator
set at 0 ppm
Reference Out of Range Threshold
(including hysteresis)
6
DS1
-64
-83
+64
+83
ppm
The 20 MHz master clock oscillator
set at 0 ppm
7
E1
-100
-130
+100
+130
ppm
The 20 MHz master clock oscillator
set at 0 ppm
8
PDH Stratum 3 / SDH
-9.2
-12
+9.2
+12
ppm
The 20 MHz master clock oscillator
set at 0 ppm
40
40
s
±64 ppm frequency offset,
SEC_MSTR = 0, HMS = 1,
TIE_CLR = 1, and FASTLOCK=0.
Lock Time
9
DS1 (1.8 Hz filter - all reference
frequencies)
44
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Performance Characteristics* - Functional (continued)
Characteristics
Min.
Max.
Units
Notes
10
E1 (1.8 Hz filter - all reference
frequencies)
40
50
s
±100 ppm frequency offset,
SEC_MSTR = 0, HMS = 1,
TIE_CLR = 1, and FASTLOCK=0
11
PDH Stratum 3 (1.8 Hz filter - all
reference frequencies)
48
50
s
±9.2 ppm frequency offset,
SEC_MSTR = 0, HMS = 1,
TIE_CLR = 1, and FASTLOCK=0
12
SDH (3.6 Hz filter - all reference
frequencies)
40
40
s
±9.2 ppm frequency offset,
SEC_MSTR = 0, HMS = 1,
TIE_CLR = 1, and FASTLOCK=0
13
SEC_MSTR = 1 (14 Hz filter - 2 kHz
reference)
25
25
s
Up to ±100 ppm frequency offset,
HMS = 1, TIE_CLR = 1, and
FASTLOCK=0
14
SEC_MSTR = 1 (58 Hz filter - 8 kHz
reference)
15
15
s
Up to ±100 ppm frequency offset,
HMS = 1, TIE_CLR = 1, and
FASTLOCK=0
15
SEC_MSTR = 1 (922 Hz filter 1.544 MHz and greater reference
frequencies)
1
1
s
Up to ±100 ppm frequency offset,
HMS = 1, TIE_CLR = 1, and
FASTLOCK=0
16
fast lock
1
1
s
Up to ±100 ppm frequency offset,
HMS = 1, TIE_CLR = 1, and
FASTLOCK=1
TIE_CLR=1
Output Phase Continuity (MTIE)
17
Reference switching
13
ns
18
Switching from Normal mode to
Holdover mode
0
ns
19
Switching from Holdover mode to
Normal mode
13
ns
TIE_CLR=1 and HMS=1
Output Phase Slope
20
DS1 / E1 / PDH Stratum 3
61
µs/s
SEC_MSTR=0
21
SDH
7.5
µs/s
SEC_MSTR=0
22
SEC_MSTR=1: clock redundancy
support
9.5
ms/s
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
45
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Performance Characteristics*: Input Wander and Jitter Tolerance Conformance
Input reference
frequency
Standard
Interface
1
1.544 MHz
Telcordia GR-1244-CORE
DS1 Line timing,
DS1 External timing
2
2.048 MHz
ITU-T G.823
2048 kbit/s
3
19.44 MHz
ITU-T G.813
Option 1
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
Performance Characteristics*: Output Jitter Generation - ANSI T1.403 conformance
ANSI T1.403
Jitter Generation Requirements
Signal
Jitter
measurement
filter
Limit in
UI
Equivalent
limit in the
time domain
ZL30105
maximum jitter
generation
Units
DS1 Interface
1
2
C1.5o (1.544 MHz)
8 kHz to 40 kHz
0.07 UIpp
45.3
0.20
nspp
10 Hz to 40 kHz
0.5 UIpp
324
0.23
nspp
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
Performance Characteristics*: Output Jitter Generation - ITU-T G.747 conformance
ITU-T G.747
Jitter Generation Requirements
Signal
Jitter
measurement
filter
Limit in
UI
Equivalent
limit in the
time domain
ZL30105
maximum jitter
generation
7.92
0.13
Units
DS2 Interface
1
C6o (6.312 MHz)
10 Hz to 60 kHz
0.05 UIpp
nspp
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
Performance Characteristics*: Output Jitter Generation - ITU-T G.812 conformance
ITU-T G.812
Jitter Generation Requirements
Signal
Jitter
measurement
filter
Limit in
UI
Equivalent
limit in the
time domain
ZL30105
maximum jitter
generation
24.4
0.26
Units
E1 Interface
1
C2o (2.048 MHz)
20 Hz to 100 kHz
0.05 UIpp
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
46
Zarlink Semiconductor Inc.
nspp
ZL30105
Data Sheet
Performance Characteristics*: Measured Output Jitter - GR-253-CORE and T1.105.03 conformance
Telcordia GR-253-CORE and ANSI T1.105.03
Jitter Generation Requirements
Signal
Jitter
Measurement
Filter
Limit in
UI
(1 UI = 6.4 ns)
Equivalent
limit in time
domain
ZL30105
maximum jitter
generation
Units
OC-3 Interface
1
C19o
2
3
4
65 kHz to 1.3 MHz
0.15 UIpp
0.96
0.22
nspp
12 kHz to1.3 MHz
(Category II)
0.1 UIpp
0.64
0.22
nspp
64
19
psrms
9.65
0.22
nspp
500 Hz to 1.3 MHz
0.01 UIrms
1.5 UIpp
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
Performance Characteristics*: Measured Output Jitter - G.813 conformance (Option 1 and Option 2)
ITU-T G.813
Jitter Generation Requirements
Signal
Jitter
Measurement
Filter
Limit in
UI
(1 UI = 6.4 ns)
Equivalent limit
in time domain
ZL30105
maximum jitter
generation
Units
STM-1 Option 1 Interface
1
C19o
2
65 kHz to 1.3 MHz
0.1 UIpp
0.64
0.22
nspp
500 Hz to 1.3 MHz
0.5 UIpp
3.22
0.22
nspp
0.1 UIpp
0.64
0.22
nspp
STM-1 Option 2 Interface
3
C19o
12 kHz to1.3 MHz
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
47
Zarlink Semiconductor Inc.
ZL30105
Data Sheet
Performance Characteristics* - Unfiltered Jitter Generation
Characteristics
Max.
[nspp]
1
C1.5o (1.544 MHz)
0.42
2
C2o (2.048 MHz)
0.38
3
C3o (3.088 MHz)
0.53
4
C4o (4.096 MHz)
0.30
5
C6o (6.312 MHz)
0.58
6
C8o (8.192 MHz)
0.22
7
C8.4o (8.448 MHz)
0.55
8
C16o (16.384 MHz)
0.23
9
C19o (19.44 MHz)
0.42
10
C32o (32.768 MHz)
0.20
11
C34o (34.368 MHz)
0.56
12
C44o (44.736 MHz)
0.60
13
C65o (65.536 MHz)
0.22
14
F2ko (2 kHz)
0.27
15
F4o (8 kHz)
0.43
16
F8o (8 kHz)
0.43
17
F16o (8 kHz)
0.44
18
F32o (8 kHz)
0.43
19
F65o (8 kHz)
0.46
Notes
* Supply voltage and operating temperature are as per Recommended Operating Conditions.
7.0
References
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