ETC ACS8530

ACS8530 SETS
Synchronous Equipment Timing Source for Stratum
2/3E Systems
ADVANCED COMMUNICATIONS
COMMUNICATION
Description
PRODUCT BRIEF
Features
The ACS8530 is the industry standard, highly integrated,
single-chip solution for the Synchronous Equipment
Timing Source (SETS) function in a SONET or SDH
Network Element. The device generates SONET or SDH
Equipment Clocks (SEC) and Frame Synchronization
clocks. The ACS8530 is fully compliant with the required
international specifications and standards.
The device supports Free-run, Locked and Holdover
modes. It also supports all three types of reference clock
source: Recovered Line Clock, PDH Network, and Node
Synchronization. The ACS8530 generates independent
SEC and BITS/SSU clocks, an 8 kHz Frame
Synchronization clock and a 2 kHz Multi-Frame
Synchronization clock.
Two ACS8530 devices can be used together in a Master/
Slave configuration mode allowing system protection
against a single ACS8530 failure.
The ACS8530 set-up is made simple using configuration
registers. These are set by Customer software, via a
microprocessor port. Semtech can provide an Evaluation
Board and software package to help customers evaluate
the device against their requirements.
‹ Suitable for Stratum 2, 3E, 3, 4E and 4 SONET
Minimum Clock (SMC) or SONET/SDH Equipment
Clock (SEC) applications (to Telcordia 1244-CORE
Stratum 3E and GR-253, and ITU-T G.812 Type III and
G.813 specifications)
‹ Accepts 14 individual input reference clocks, all with
robust input clock source quality monitoring
‹ Simultaneously generates nine output clocks, plus
two Sync pulse outputs
‹ Absolute Holdover accuracy better than 3 x 10-10
(manual), 7.5 x 10-14 (instantaneous); Holdover
stability defined by choice of external XO
‹ Programmable PLL bandwidth, for wander and jitter
tracking/attenuation, 0.5 mHz to 70 Hz in 18 steps
‹ Automatic hit-less source switchover on loss of input
‹ Phase Transient Protection and Phase Build-out on
locked to reference and on reference switching
‹ Microprocessor interface - Intel, Motorola, Serial,
Multiplexed, or boot from EPROM
‹ Output phase adjustment in 6 ps steps up to ±200 ns
The ACS8530 supports IEEE 1149.1 JTAG boundary scan.
‹ IEEE 1149.1 JTAG Boundary Scan
Block Diagram
‹ Single 3.3 V operation. 5 V tolerant
Figure 1
Block Diagram of the ACS8530 SETS
T4 DPLL/Freq. Synthesis
2 x AMI
10 x TTL
2 x PECL/LVDS
Programmable;
64/8 kHz (AMI)
2 kHz
4 kHz
N x 8 kHz
1.544/2.048 MHz
6.48 MHz
19.44 MHz
25.92 MHz
38.88 MHz
51.84 MHz
77.76 MHz
155.52 MHz
TCK
TDI
TMS
TRST
TDO
T4
Selector
Optional
Divider, 1/n
n = 1 to 214
PFD
Digital
Loop
Filter
T4 APLL
DTO
Frequency
Dividers
Input
Port
Monitors
and
Selection
Control
T0 APLL
(output)
T0 DPLL/Freq. Synthesis
14 x SEC
T0
Selector
IEEE
1149.1
JTAG
Chip
Clock
Generator
Optional
Divider, 1/n
n = 1 to 214
PFD
Priority Register Set
Table
Digital
Loop
Filter
Microprocessor
Port
OCXO
Frequency
Dividers
DTO
Output
Ports
TO1
to
TO7
Outputs
T01-TO7:
E1/DS1 (2.048/
1.544 MHz)
and frequency
multiples:
1.5 x, 2 x, 3 x
4 x, 6 x, 12 x
16 x and 24 x
E3/DS3
2 kHz
8 kHz
and OC-N* rates
TO8
&
TO9
T08: AMI
TO9: E1/DS1
TO10
&
TO11
TO10: 8 kHz
(FrSync)
TO11: 2 kHz
(MFrSync)
TO APLL
(feedback)
OC-N* rates =
OC-1 51.84 MHz
OC-3 155.52 MHz
and derivatives:
6.48 MHz
19.44 MHz
25.92 MHz
38.88 MHz
51.84 MHz
77.76 MHz
155.52 MHz
311.04 MHz
F8530D_001BLOCKDIA_09
Revision 2.00/February 2003 © Semtech Corp.
Page 1
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ACS8530 SETS
ADVANCED COMMUNICATION
Contents
PRODUCT BRIEF
Pin Description
Description ..................................................................................1
Block Diagram .............................................................................1
Features ......................................................................................1
Contents ......................................................................................2
Pin Diagram ................................................................................2
Pin Description ............................................................................2
Table 1 No Connections and Internally Connected
Pin No.
3, 4, 17,
22, 96, 97,
98
Symbol
IC1, IC2, IC3,
IC4, IC5, IC6,
IC7
I/O
Type
-
-
Description
Internally Connected: Leave to Float.
Table 2 Power Pins
Introduction .................................................................................4
I/O
Type
12, 13,
16
VD1+, VD3+,
VD2+
P
-
Supply Voltage: Digital supply to gates
in analog section, +3.3 Volts ±10%.
26
VAMI+
P
-
Supply Voltage: Digital supply to AMI
output, +3.3 Volts ±10%.
PLL Paths ............................................................................5
33,
39
VDD_DIFFa,
VDD_DIFFb
P
-
Supply Voltage: Digital supply for
differential ports, +3.3 Volts ±10%.
Outputs ...............................................................................6
44
VDD5
P
-
Digital Supply for +5 Volts Tolerance to
Input Pins. Connect to +5 Volts (±10%)
for clamping to +5 Volts. Connect to
VDD for clamping to +3.3 Volts. Leave
floating for no clamping, input pins
tolerant up to +5.5 Volts.
Register Map ...............................................................................9
50, 61,
85, 86
VDDa, VDDd,
VDDc, VDDb
P
-
Supply Voltage: Digital supply to logic,
+3.3 Volts ±10%.
Ordering Information ............................................................... 12
6
VA1+
P
-
Supply Voltage: Analog supply to clock
multiplying PLL, +3.3 Volts ±10%.
19
91
VA2+,
VA3+
P
-
Supply voltage: Analog supply to output
PLLs, +3.3 Volts ±10%.
11,
14,
15
DGND1,
DGND3,
DGND2
P
-
Supply Ground: Digital ground for
components in PLLs.
49,
62,
84,
87
DGNDa
DGNDd,
DGNDc,
DGNDb
P
-
Supply Ground: Digital ground for logic.
29
GND_AMI
P
-
Supply Ground: Digital ground for AMI
output.
32,
38
GND_DIFFa,
GND_DIFFb
P
-
Supply Ground: Digital ground for
differential ports.
1, 5,
20, 92
AGND, AGND1,
AGND2, AGND3
P
-
Supply Ground: Analog grounds.
General Description ....................................................................4
Inputs ..................................................................................4
Monitors ..............................................................................4
Pin No.
Symbol
Modes of Operation ...........................................................7
Performance .......................................................................8
Typical Application .............................................................8
Disclaimers ...................................................................... 12
Contacts ........................................................................... 12
Pin Diagram
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
SONSDHB
MSTSLVB
IC7
IC6
IC5
TO9
TO5
TO4
AGND3
VA3+
TO3
TO2
TO1
DGNDb
VDDb
VDDc
DGNDc
AD0
AD1
AD2
AD3
AD4
AD5
AD6
AD7
Figure 2 ACS8530 Pin Diagram
AGND
TRST
IC1
IC2
AGND1
VA1+
TMS
INTREQ
TCK
REFCLK
DGND1
VD1+
VD3+
DGND3
DGND2
VD2+
IC3
SRCSW
VA2+
AGND2
TDO
IC4
TDI
I1
I2
ACS8530
SONET/SDH SETS
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
VAMI+
TO8NEG
TO8POS
GND_AMI
FrSync
MFrSync
GND_DIFFa
VDD_DIFFa
TO6POS
TO6NEG
TO7POS
TO7NEG
GND_DIFFb
VDD_DIFFb
I5POS
I5NEG
I6POS
I6NEG
VDD5
SYNC2K
I3
I4
I7
DGNDa
VDDa
1
2
3
4
5
6
7
8
9
10
11
1
12
13
14
15
16
17
18
19
20
21
22
23
24
25
Revision 2.00/February 2003 © Semtech Corp.
F8530D_002PINDIAG_04
RDY
PORB
ALE
RDB
WRB
CSB
A0
A1
A2
A3
A4
A5
A6
DGNDd
VDDd
UPSEL0
UPSEL1
UPSEL2
I14
I13
I12
I11
I10
I9
I8
Description
Table 3 Other Pins
I/O
Type
2
Pin No.
TRST
I
TTLD
JTAG Control Reset Input: TRST = 1 to
enable JTAG Boundary Scan mode.
TRST = 0 for Boundary Scan stand-by
mode, still allowing correct device
operation. If not used connect to GND
or leave floating.
7
TMS
I
TTLU
JTAG Test Mode Select: Boundary Scan
enable. Sampled on rising edge of TCK.
If not used connect to VDD or leave
floating.
8
INTREQ
O
TTL/
CMOS
9
TCK
I
TTLD
JTAG Clock: Boundary Scan clock input.
If not used connect to GND or leave
floating.
10
REFCLK
I
TTL
Reference Clock: 12.800 MHz (refer to
section headed Local Oscillator Clock).
Page 2
Symbol
Description
Interrupt Request: Programmable
Active High/Low, open source/drain
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ACS8530 SETS
ADVANCED COMMUNICATION
PRODUCT BRIEF
Table 3 Other Pins (cont...)
Pin No.
I/O
Type
18
SRCSW
I
TTLD
Source Switching: Force Fast Source
Switching.
I/O
Type
Description
70
CSB
I/O
TTLU
Chip Select (Active Low): This pin is
asserted Low by the microprocessor to
enable the microprocessor interface output in EPROM mode only.
21
TDO
O
TTL/
CMOS
JTAG Output: Serial test data output.
Updated on falling edge of TCK. If not
used leave floating.
71
WRB
I
TTLU
Write (Active Low): This pin is asserted
Low by the microprocessor to initiate a
write cycle. In Motorola mode, WRB = 1
for Read.
23
TDI
I
TTL
JTAG Input: Serial test data Input.
Sampled on rising edge of TCK. If not
used connect to VDD or leave floating.
24
I1
I
AMI
Input Reference 1: Composite clock
64 kHz + 8 kHz.
72
RDB
I
TTLU
Read (Active Low): This pin is asserted
Low by the microprocessor to initiate a
read cycle.
25
I2
I
AMI
Input Reference 2: Composite clock
64 kHz + 8 kHz.
73
ALE
I
TTLD
Address Latch Enable: This pin
becomes the address latch enable from
the microprocessor. When this pin
transitions from Low to High, the
address bus inputs are latched into the
internal registers. ALE = SCLK in Serial
mode.
27
TO8NEG
O
AMI
Output Reference 8: Composite clock,
64 kHz + 8 kHz negative pulse.
28
TO8POS
O
AMI
Output Reference 8: Composite clock,
64 kHz + 8 kHz positive pulse.
30
FrSync
O
TTL/
CMOS
Output Reference 10: 8 kHz Frame
Sync output.
74
PORB
I
TTLU
Power-On Reset: Master reset. If PORB
is forced Low, all internal states are set
to default values.
31
MFrSync
O
TTL/
CMOS
Output Reference 11: 2 kHz MultiFrame Sync output.
34,
35
TO6POS,
TO6NEG
O
LVDS/
PECL
Output Reference 6: Programmable,
default 38.88 MHz, default type LVDS.
75
RDY
O
TTL/
CMOS
Ready/Data Acknowledge: This pin is
asserted High to indicate the device
has completed a read or write
operation.
36,
37
TO7POS,
TO7NEG
O
PECL/
LVDS
Output Reference 7: Programmable,
default 19.44 MHz, default type PECL.
76 - 83
AD(7:0)
I/O
TTLD
Address/Data: Multiplexed
data/address bus depending on the
microprocessor mode selection. AD(0)
is SDO in Serial mode.
40,
41
I5POS,
I5NEG
I
LVDS/
PECL
Input Reference 5: Programmable,
default 19.44 MHz, default type LVDS.
42,
43
I6POS,
I6NEG
I
PECL/
LVDS
Input Reference 6: Programmable,
default 19.44 MHz, default type PECL.
88
TO1
O
TTL/
CMOS
Output Reference 1: Programmable,
default 6.48 MHz.
45
SYNC2K
I
TTLD
External Sync Input: 2 kHz, 4 kHz or 8
kHz for frame alignment.
89
TO2
O
TTL/
CMOS
Output Reference 2: Programmable,
default 38.88 MHz.
46
I3
I
TTLD
Input Reference 3: Programmable,
default 8 kHz.
90
TO3
O
TTL/
CMOS
Output Reference 3: Programmable,
default 19.44 MHz.
47
I4
I
TTLD
Input Reference 4: Programmable,
default 8 kHz.
93
TO4
O
TTL/
CMOS
Output Reference 4: Programmable,
default 38.88 MHz.
48
I7
I
TTLD
Input Reference 7: Programmable,
default 19.44 MHz.
94
TO5
O
TTL/
CMOS
Output Reference 5: Programmable,
default 77.76 MHz.
51
I8
I
TTLD
Input Reference 8: Programmable,
default 19.44 MHz.
95
TO9
O
TTL/
CMOS
52
I9
I
TTLD
Input Reference 9: Programmable,
default 19.44 MHz.
Output Reference 9:
1.544/2.048 MHz, as per ITU G.783
BITS requirements.
99
MSTSLVB
I
TTLU
53
I10
I
TTLD
Input Reference 10: Programmable,
default 19.44 MHz.
Master/Slave Select: Sets the state of
the device operating mode, Reg. 34,
Bit 1.
54
I11
I
TTLD
Input Reference 11: Programmable,
default (Master mode) 1.544/2.048
MHz, default (Slave mode) 6.48 MHz.
100
SONSDHB
I
TTLD
55
I12
I
TTLD
Input Reference 12: Programmable,
default 1.544/2.048 MHz.
56
I13
I
TTLD
Input Reference 13: Programmable,
default 1.544/2.048 MHz.
57
I14
I
TTLD
Input Reference 14: Programmable,
default 1.544/2.048 MHz.
SONET or SDH frequency select: Sets
the initial power up state (or state after
a PORB) of the SONET/SDH frequency
selection registers, Reg. 34, Bit 2 and
Reg. 38, Bit 5 and Bit 6, and Reg 64
bit 4. When set Low, SDH rates are
selected (2.048 MHz etc.) and when
set High, SONET rates are selected
(1.544 MHz etc.) The register states
can be changed after power-up by
software.
58 - 60
UPSEL(2:0)
I
TTLD
Microprocessor Select: Configures the
interface for a particular
microprocessor type at reset.
63 - 69
Symbol
Table 3 Other Pins (cont...)
A(6:0)
I/O
U
TTLD
Description
Pin No.
Microprocessor Interface Address:
Address bus for the microprocessor
interface registers. A(0) is SDI in Serial
mode - output in EPROM mode only.
Revision 2.00/February 2003 © Semtech Corp.
Symbol
Note...I = Input, O = Output, P = Power, TTLU = TTL input with pull-up
resistor, TTLD = TTL input with pull-down resistor
Page 3
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ACS8530 SETS
ADVANCED COMMUNICATION
Introduction
PRODUCT BRIEF
General Description
The ACS8530 SETS device is the industry standard singlechip solution for all of the SETS functions in both SONET
and SDH Network Elements. It is a highly integrated, and
easily configurable device which generates and maintains
accurate and stable SEC and Frame/Multi-Frame
Synchronization pulse outputs, compliant with the
required international telecom specifications and
standards. The ACS8530 provides a simple, compact,
highly flexible synchronization solution, which can be
easily tailored for use with a range of transmission
formats and rates, via software configuration.
The ACS8530 employs various mechanisms to maintain
the integrity of its output clocks when its input clocks fail
or fall below the required specification levels. By
smoothing out the effects of these input anomalies, the
ACS8530 improves the overall stability and reliability of
the downstream system synchronization, which
translates to improved quality of service.
In addition to the benefits of having all the SETS
functionality on one chip, a key architectural advantage
that the ACS8530 has over traditional solutions is in the
use of Digital Phase Locked Loop (DPLL) technology for
precise and repeatable performance over temperature or
voltage variations and between parts.
Semtech can provide an Evaluation Board and an
intuitive, GUI-based Software package so that designers
can rapidly appraise the ACS8530 SETS device and see
for themselves the benefits that a Semtech SETS solution
can bring to their designs.
Figure 3 Evaluation Software Graphical User Interface
Inputs
The ACS8530 SETS device accepts 14 input clocks via the
input ports (10 x TTL, 2 x PECL/LVDS, 2 x AMI). All the
TTL/CMOS ports are 3 V and 5 V compatible (with
clamping if required by connecting the VDD5 pin). The AMI
inputs are typically ±1 V A.C. coupled.
Input frequencies supported range from 2 kHz to
155.52 MHz. Common E1, DS1, OC-3 and sub-divisions
are supported as spot frequencies to which the DPLLs will
directly lock.
Any input frequency, up to 100 MHz, that is a multiple of
8 kHz can also be locked to via a built-in programmable
divider. The ACS8530 supports all three types of
reference clock source: Recovered Line Clock, PDH
Network Synchronization Timing and Node
Synchronization. Refer to Table 4 for details of each input
port.
Monitors
A monitoring function constantly appraises the
frequency/activity of each input reference source, and
reports anomalous behavior. Each of the 14 input
monitors is individually configurable, allowing flags or
interrupts to be raised which can influence both the
operating state of the device and which inputs are
available for selection by the PLL circuitry. Any reference
source which suffers a loss-of-activity or clock-out-of-band
condition will be declared as unavailable.
Anomalies detected by the activity detector are integrated
in a Leaky Bucket Accumulator. Occasional anomalies do
not cause the Accumulator to cross the alarm setting
threshold, so the selected reference source is retained.
Persistent anomalies cause the alarm setting threshold to
be crossed and result in the selected reference source
being rejected.
The ACS8530 performs frequency monitoring to identify
reference sources which have drifted outside the
acceptable frequency range measured with respect either
to the output clock or to the XO clock. A soft alarm is
raised if the drift is outside ±11.43 ppm and a hard alarm
is raised if the drift is outside ±15.24 ppm.
Revision 2.00/February 2003 © Semtech Corp.
Page 4
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ACS8530 SETS
ADVANCED COMMUNICATION
PRODUCT BRIEF
Table 4 Input Reference Source Selection and Priority Table
Port Number
Channel Number
Input Port
Technology
Frequencies Supported
Default Priority
I1
0001
AMI
64/8 kHz (composite clock, 64 kHz + 8 kHz)
Default (SONET): 64/8 kHz Default (SDH): 64/8 kHz
2
I2
0010
AMI
64/8 kHz (composite clock, 64 kHz + 8 kHz)
Default (SONET): 64/8 kHz Default (SDH): 64/8 kHz
3
I3
0011
TTL/CMOS
Up to 100 MHz (see Note (i))
Default (SONET): 8 kHz Default (SDH): 8 kHz
4
I4
0100
TTL/CMOS
Up to 100 MHz (see Note (i))
Default (SONET): 8 kHz Default (SDH): 8 kHz
5
I5
0101
LVDS/PECL LVDS
default
Up to 155.52 MHz (see Note (ii))
Default (SONET): 19.44 MHz Default (SDH): 19.44 MHz
6
I6
0110
PECL/LVDS PECL
default
Up to 155.52 MHz (see Note (ii))
Default (SONET): 19.44 MHz Default (SDH): 19.44 MHz
7
I7
0111
TTL/CMOS
Up to 100 MHz (see Note (i))
Default (SONET): 19.44 MHz Default (SDH): 19.44 MHz
8
I8
1000
TTL/CMOS
Up to 100 MHz (see Note (i))
Default (SONET): 19.44 MHz Default (SDH): 19.44 MHz
9
I9
1001
TTL/CMOS
Up to 100 MHz (see Note (i))
Default (SONET): 19.44 MHz Default (SDH): 19.44 MHz
10
I10
1010
TTL/CMOS
Up to 100 MHz (see Note (i))
Default (SONET): 19.44 MHz Default (SDH): 19.44 MHz
11
I11
1011
TTL/CMOS
Up to 100 MHz (see Note (i))
Default (Master) (SONET): 1.544 MHz Default (Master) (SDH): 2.048 MHz Default (Slave) 6.48 MHz
12/1
(Note (iii))
I12
1100
TTL/CMOS
Up to 100 MHz (see Note (i))
Default (SONET): 1.544 MHz Default (SDH): 2.048 MHz
13
I13
1101
TTL/CMOS
Up to 100 MHz (see Note (i))
Default (SONET): 1.544 MHz Default (SDH): 2.048 MHz
14
I14
1110
TTL/CMOS
Up to 100 MHz (see Note (i))
Default (SONET): 1.544 MHz Default (SDH): 2.048 MHz
15
Notes: (i) TTL ports (compatible also with CMOS signals) support clock speeds up to 100 MHz, with the highest spot frequency being
77.76 MHz. The actual spot frequencies are: 2 kHz, 4 kHz, 8 kHz (and N x 8 kHz), 1.544 MHz (SONET)/2.048 MHz (SDH), 6.48 MHz,
19.44 MHz, 25.92 MHz, 38.88 MHz, 51.84 MHz, 77.76 MHz. SONET or SDH input rate is selected via Reg. 34 bit 2, ip_sonsdhb).
(ii) PECL and LVDS ports support the spot clock frequencies listed above plus 155.52 MHz (and 311.04 MHz for TO6 only).
(iii) Input port I11 is set at priority 12 on the Master SETS IC and priority 1 on the Slave SETS IC, as default on power up (or PORB). The
default setup of Master or Slave I11 priority is determined by the MSTSLVB pin.
PLL Paths
There are two main paths through the device, T0 and T4;
these names refer to the pair of PLLs (one digital, one
analog) that process the selected inputs to synthesize the
required output frequencies. The T0 and T4 paths are
independent of each other in the default state, allowing
two separate inputs to be in independent use in the
device at the same time. However the interconnections
between PLL blocks within and between these paths is
highly configurable, via register control. Several different
paths can be obtained to provide the output frequencies
and jitter performance required (see application note ANSETS-7). In many configurations the paths are combined
so that only the T0, or only the T4 input can be used, not
both at the same time.
Both paths include an input selector, an optionally
selected divider, a DPLL, a multiplying and filtering APLL
and an output frequency divider. In each path the DPLLs
Revision 2.00/February 2003 © Semtech Corp.
are shown in the Block Diagram as comprising a generic
Phase and Frequency Detector (PFD), a Digital Loop filter,
and a Digital Timed Oscillator (DTO); however the DPLL
architecture in the T0 path is actually more complex than
that of the T4 path and provides greater functionality.
Features of the T0 and T4 PLL Paths
z
Automatic source selection according to input
priorities and quality level
z
Different quality levels (activity alarm thresholds) for
each input
z
Variable bandwidth, lock range and damping factor
z
Direct PLL locking to common SONET/SDH input
frequencies or any multiple of 8 kHz
z
Automatic mode switching between Free-run, Locked
and Holdover states
Page 5
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ACS8530 SETS
ADVANCED COMMUNICATION
PRODUCT BRIEF
z
Fast detection on input failure and entry into Holdover
mode (holds at the last good frequency value)
z
Frequency translation between input and output rates
via direct digital synthesis
z
High accuracy digital architecture for stable PLL
dynamics combined with an APLL for low jitter final
output clocks
Table 5 Output Port Frequencies and Technologies
T0 Additional Features:
z
Non-revertive mode
z
Phase Build-out (PBO) on source switch (hit-less
source switching)
The ACS8530 can be configured to support OC-N,
E1/DS1, E3/DS3 and BITS outputs, together with and an
8 kHz Frame Synchronization clock and a 2 kHz MultiFrame Synchronization clock. Tables 5 and 6 summarize
the output frequency/jitter options and technologies
supported for each output port.
Port Name
Output Port
Technology
T01
TTL/CMOS
T02
TTL/CMOS
T03
TTL/CMOS
TTL/CMOS
z
PBO following phase hit on locked-to source
T04
T05
TTL/CMOS
z
I/O phase offset control
T06
z
Greater programmable bandwidth from 0.5 mHz to
70 Hz in 18 steps (T4 path programmable bandwidth
in 3 steps, 18, 35 and 70 Hz)
LVDS/PECL
(LVDS default)
T07
PECL/LVDS
(PECL default)
T08
AMI
z
Noise rejection on low frequency inputs
z
Manual Holdover frequency control
z
Controllable automatic Holdover frequency filtering
z
Frame Sync pulse alignment
Either the software or an internal state machine controls
the operation of the DPLL in the T0 path. The state
machine for the T4 path is very simple and cannot be
manually/externally controlled, however the overall
operation can be controlled by using manual reference
source selection. The T4 path can be used to measure
phase difference between two inputs.
The T0 path DPLL always produces an output at
77.76 MHz to feed the APLL, regardless of the frequency
selected at the output pins. The T4 path can be operated
at a number of frequencies. This is to enable the
generation of extra output frequencies, which cannot be
easily related to 77.76 MHz. When the T4 path is selected
to lock to the T0 path, the T4 DPLL locks to 8 kHz supplied
from the T0 DPLL. This is because all of the frequencies of
operation of the T4 path can be divided to 8 kHz and this
ensures synchronization of all the frequencies (except
2 kHz) within the two paths.
Outputs
The PLLs work together to ensure a number of
frequencies are simultaneously available for selection at
the 11 output ports (8 x TTL, 2 x PECL/LVDS, 1 x AMI).
The various configurations make the ACS8530 capable of
generating a total of 55 possible output frequencies.
Revision 2.00/February 2003 © Semtech Corp.
Frequencies Supported
See Table 6
64/8 kHz (composite clock, 64 kHz + 8 kHz),
fixed frequency.
T09
TTL/CMOS
Either 1.544 MHz or 2.048 MHz.
T010
TTL/CMOS
FrSync, 8 kHz programmable pulse width and
polarity, see Reg. 7C.
T011
TTL/CMOS
MFrSync, 2 kHz programmable pulse width and
polarity, see Reg. 7C.
Table 6 TO1 to TO7 Frequency/Jitter Options
Frequency (MHz)
2 kHz
Jitter Level (typ)
rms (ps)
60
8 kHz
pk-pk (ns)
0.6
60
0.6
1.536
(not TO4/TO5)
250
1.5
1.544
(not TO4/TO5)
150
1.0
2.048
220
1.2
2.0586667
150
1.0
2.316
(not TO4/TO5)
2.7306667
2.796
(not TO4/TO5)
110
0.75
220
1.2
110
1.0
3.088
110
0.75
3.728
110
1.0
4.096
via Digital1 (not TO7) or
Digital2 (not TO6)
3800
13
4.296
(not TO4/TO5)
120
1.0
4.86
(not TO4/TO5)
60
0.6
5.728
120
1.0
6.144
250
1.5
6.176
150
1.0
6.48
60
0.6
8.192
220
1.2
8.2346667
760
2.6
9.264
110
0.75
10.922667
250
1.6
11.184
110
1.0
12.288
250
1.5
12.352
110
0.75
16.384
220
1.2
16.46933
760
2.6
17.184
120
1.0
Page 6
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ACS8530 SETS
ADVANCED COMMUNICATION
PRODUCT BRIEF
Table 6 TO1 to TO7 Frequency/Jitter Options (cont...)
Jitter Level (typ)
Frequency (MHz)
18.528
rms (ps)
110
pk-pk (ns)
0.75
19.44
60
0.6
21.84533
250
1.6
22.368
110
1.0
24.576
250
1.5
24.704
110
0.75
25.92
60
0.6
32.768
220
1.2
34.368
120
1.0
37.056
110
0.75
38.88
60
0.6
44.736
110
1.0
49.152
(TO4/TO5 only)
250
1.5
49.152
(TO6/TO7 only)
900
4.5
49.408
(TO4/TO5 only)
150
1.0
49.408
(TO6/TO7 only)
760
2.6
60
0.6
65.536
(TO4/TO5 only)
220
1.2
65.536
(TO6/TO7 only)
120
1.0
51.84
68.736
120
1.0
74.112
(TO4/TO5 only)
110
0.75
74.112
(TO6/TO7 only)
110
0.75
60
0.6
77.76
89.472
(TO4/TO5 only)
110
1.0
98.304
(TO6 only)
900
4.5
98.816
(TO6 only)
760
2.6
131.072
(TO6 only)
250
1.6
137.472
(TO4/TO5 only)
120
1.0
148.224
(TO6 only)
110
0.75
60
0.6
(TO6 only)
60
0.6
155.52
311.04
Input Selection Priorities
Each input reference can be programmed with a priority
number (see Table 4) allowing references to be chosen
according to the highest priority valid input. The two paths
(T0 and T4) have their own separate priority settings so
that the paths can operate independently. Both paths
operate either automatic or external source selection.
Table 4 gives details of the input reference ports. Specific
frequencies and priorities are set by configuration.
Automatic Selection
Under normal operation, the input reference sources are
selected automatically by an order of priority. But, for
special circumstances such as chip or board testing, the
selection may be forced by configuration.
Automatic operation selects a reference source based on
its predefined priority and its current availability. A table is
maintained which lists all reference sources in the order
of priority. This is initially defined by the default
configuration and can be changed, via the microprocessor
interface, by the Network Manager. In this way, when all
the defined sources are active and valid, the source with
the highest programmed priority is selected but, if this
source fails, then next-highest source is selected.
Modes of Operation
The device has three principle modes of operation:
Free-run, Locked, and Holdover.
In Free-run mode, the ACS8530 is not synchronized to an
input reference source. It generates a stable, low-noise
clock signal derived from, and with the same frequency
accuracy as, the external oscillator. The accuracy can be
enhanced via software calibration to within ±0.02 ppm.
In Locked mode, the ACS8530 selects the most
appropriate input reference source from its 14 available
inputs and generates a stable, low-noise clock signal
locked to the selected reference. When the Locked mode
is achieved, the output signal is phase locked to the
selected input reference source. The selected input
reference source is determined by the priority table.
When the ACS8530 is in Locked mode, the output
frequency and phase follows that of the selected input
reference source.
Revision 2.00/February 2003 © Semtech Corp.
In Holdover mode, the ACS8530 generates a stable, lownoise clock signal from the internal oscillator, adjusted to
match the last known good frequency of the last selected
reference source. The device uses stored data, acquired
when the input reference source was still valid, to control
its output frequency. The ACS8530 provides several
configurable modes for refining Holdover operation.
Ultra Fast Switching
Reference sources are monitored using a Leaky Bucket
approach to allow source qualification criterion to be
monitored. A reference source is normally disqualified
after the Leaky Bucket monitor thresholds have been
crossed. An option for a faster disqualification has been
implemented so that a loss of activity of just a few
reference clock cycles will raise an alarm and cause a
reference switch.
External Protection Switching
External Switching mode, for fast switching between
inputs I3 or I5 and I4 or I6, can also be triggered directly
from a dedicated pin (SRCSW).
Page 7
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ACS8530 SETS
ADVANCED COMMUNICATION
Performance
PRODUCT BRIEF
that the overall system performance still maintains the
advantage of consistent behavior provided by the digital
approach.
Conformance
In all modes of Operation, the frequency accuracy, jitter
and drift performance of the clocks meet the
requirements of the following specifications:
The DPLLs are clocked by the external Oscillator module
(OCXO) therefore the Free-run or Holdover frequency
stability is only determined by the stability of the external
oscillator module. This second key advantage confines all
temperature critical components to one well defined and
pre-calibrated module, whose performance can be
chosen to match the application; for example, an OCXO
for Stratum 3E applications.
ITU-T: G.736, G.742, G783, G.812, G.813, G.822, G.823,
G.824, G.825.
Telcordia: GR-253-CORE, Issue 3; GR-499-CORE, Issue 2;
GR-1244-CORE, Issue 2.
ANSI: (DS1) T1 1.101-1999.
ETSI: ETS 300 462-3, ETS 300 462-5.
All performance parameters of the DPLLs are
programmable without the need to understand detailed
PLL equations. Bandwidth, damping factor and lock
range, for example, can all be set directly. The PLL
bandwidth can be set over a wide range, 0.5 mHz to 70 Hz
in 18 steps, to cover all SONET/SDH clock
synchronization applications.
Performance Benefits from DPLL/APLL Technology
The use of Digital Phase Locked Loop technology ensures
precise and repeatable performance over temperature or
voltage variations, and between parts. The overall PLL
bandwidth, loop damping, pull-in range and frequency
accuracy are all determined by digital parameters that
provides a consistent level of performance. An APLL takes
the signal from the DPLL output and provides a lower jitter
output. The APLL bandwidth is set four orders of
magnitude higher than the DPLL bandwidth. This ensures
A high level of phase and frequency accuracy is made
possible in the ACS8530 by an internal resolution of up to
54 bits and internal Holdover accuracy up to 7.5 x 10-14
(instantaneous).
Typical Application
Figure 4
Semtech’s Product Family Solution for a Typical SONET/SDH Architecture
Multiple Line cards
Line Card
Recovered Clock
Master Clock
Master Sync
Slave Clock
Slave Sync
Stand-by Clock
Stand-by Sync
Frame Sync
Multi Frame Sync
ACS8515
ACS8525
ACS8526
ACS8527
FRAMER
SERDES
E1/DS1
LINE
CARD
PROTECTION
To/from
SONET/SDH/PDH
Network
CMU
Low Jitter up to 622 MHz
Low Jitter/Low Skew
Clock
Distribution
Backplane
Slave Sync Card
Master Sync Card
Input CLK Sources
Config.
Priorities
mP/Serial Bus
SSM
Primary Ref.
Input/
output
DATA
DATA
ACS8510
ACS8520
ACS8522
ACS8530
Priorities
TCLK
CLK
Line
I/F
Unit
SETS
Output
CLKs
ACS8110
Clock
Distribution
SSM HANDLER
SEC
SetsLinecardGenApp_03
Revision 2.00/February 2003 © Semtech Corp.
Page 8
www.semtech.com
ACS8530 SETS
ADVANCED COMMUNICATION
Register Map
PRODUCT BRIEF
Table 7 Register Map
Data Bit
Address
(hex)
Default
(hex)
Register Name
RO = Read Only
R/W = Read/Write
chip_id (RO)
7 (MSB)
6
4
3
2
1
00
52
Device part number [7:0] 8 least significant bits of the chip ID
01
21
Device part number [15:8] 8 most significant bits of the chip ID
chip_revision (RO)
02
00
test_register1 (R/W)
03
14
phase_alarm
disable_180
sts_interrupts (R/W)
05
FF
I8 valid
change
I7 valid
change
06
3F
operating_
mode
main_ref_
failed
sts_current_DPLL_frequency, see
OC/OD
07
00
sts_interrupts (R/W)
08
50
Sync_ip_alarm T4_status
sts_operating (RO)
09
41
SYNC2K_
alarm
sts_priority_table (RO)
5
0 (LSB)
Chip revision number [7:0]
resync_
analog
Set to zero
8K edge
polarity
Set to zero
Set to zero
I6 valid
change
I5 valid
change
I4 valid
change
I3 valid
change
I2 valid
change
I1 valid
change
I14 valid
change
I13 valid
change
I12 valid
change
I11 valid
change
I10 valid
change
I9 valid
change
Bits [18:16] of current DPLL frequency
T4_DPLL_lock
T4_inputs_
failed
TO_DPLL_freq
_soft_alarm
AMI2_Viol
AMI2_LOS
T4_DPLL_freq
_soft_alarm
AMI1_Viol
AMI1_LOS
T0_DPLL_operating_mode
0A
00
Highest priority validated source
Currently selected source
0B
00
3rd highest priority validated source
2nd highest priority validated source
sts_current_DPLL_frequency [7:0] 0C
00
(RO)
Bits [7:0] of current DPLL frequency
[15:8] 0D 00
[18:16] 07
00
0E
00
0F
00
sts_sources_valid (RO)
sts_reference_sources (RO)
Bits [15:8] of current DPLL frequency
Bits [18:16] of current DPLL offset
I8
I7
Out-of-band
alarm (soft)
Out-of band
alarm (hard)
I6
I5
I4
I3
I2
I1
I14
I13
I12
I11
I10
I9
No Activity
alarm
Phase lock
alarm
Out-of-band
alarm (soft)
Out-of band
alarm (hard)
No activity
alarm
Phase lock
alarm
Status of Input pairs (1 & 2) 10
66
Status of I2 Input
Status of I1 Input
(3 & 4) 11
66
Status of I4 Input
Status of I3 Input
(5 & 6) 12
66
Status of I6 Input
Status of I5 Input
(7 & 8) 13
66
Status of I8 Input
Status of I7 Input
(9 & 10) 14
66
Status of I10 Input
Status of I9 Input
(11 & 12) 15
66
Status of I12 Input
Status of I11 Input
(13 & 14) 16
66
Status of I14 Input
Status of I13 Input
cnfg_ref_selection_priority (1 & 2) 18
32
programmed_priority I2
programmed_priority I1
(R/W)
(3 & 4) 19
54
programmed_priority I4
programmed_priority I3
(5 & 6) 1A
76
programmed_priority I6
programmed_priority I5
(7 & 8) 1B
98
programmed_priority I8
programmed_priority I7
(9 & 10) 1C
BA
programmed_priority I10
programmed_priority I9
(11 & 12) 1D DC
programmed_priority I12
programmed_priority I11
(13 & 14) 1E
programmed_priority I14
programmed_priority I13
FE
cnfg_ref_source_frequency_
1 20
00
Set to zero
bucket_id_1
(R/W)
2 21
00
Set to zero
bucket_id_2
Set to zero
Set to zero
3 22
00
divn_3
lock8k_3
bucket_id_3
reference_source_frequency_3
4 23
00
divn_4
lock8k_4
bucket_id_4
reference_source_frequency_4
5 24
03
divn_5
lock8k_5
bucket_id_5
reference_source_frequency_5
6 25
03
divn_6
lock8k_6
bucket_id_6
reference_source_frequency_6
7 26
03
divn_7
lock8k_7
bucket_id_7
reference_source_frequency_7
8 27
03
divn_8
lock8k_8
bucket_id_8
reference_source_frequency_8
9 28
03
divn_9
lock8k_9
bucket_id_9
reference_source_frequency_9
10 29
03
divn_10
lock8k_10
bucket_id_10
reference_source_frequency_10
11 2A
03
divn_11
lock8k_11
bucket_id_11
reference_source_frequency_11
12 2B
01
divn_12
lock8k_12
bucket_id_12
reference_source_frequency_12
13 2C
01
divn_13
lock8k_13
bucket_id_13
reference_source_frequency_13
14 2D 01
divn_14
lock8k_14
bucket_id_14
reference_source_frequency_14
cnfg_sts_remote_sources_valid
(R/W)
30
FF
31
3F
Revision 2.00/February 2003 © Semtech Corp.
Remote status, channels [8:1]
Remote status, channels [14:9]
Page 9
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ACS8530 SETS
ADVANCED COMMUNICATION
PRODUCT BRIEF
Table 7 Register Map (cont...)
Address
(hex)
Default
(hex)
Register Name
RO = Read Only
R/W = Read/Write
Data Bit
7 (MSB)
6
cnfg_operating_mode (R/W)
32
00
force_select_reference_source
(R/W)
33
0F
cnfg_input_mode
(Bit 1 RO, otherwise R/W)
34
C2
auto_extsync_
en
phalarm_
timeout
cnfg_T4_path (R/W)
35
40
Lock_T4_to_
T0
T4_dig_
feedback
cnfg_differential_inputs (R/W)
36
02
cnfg_uPsel_pins (RO)
37
02
cnfg_dig_outputs_sonsdh (R/W)
38
1F
cnfg_digtial_frequencies (R/W)
39
08
cnfg_differential_outputs (R/W)
3A
C6
cnfg_auto_bw_sel (R/W)
3B
FB
[7:0] 3C
99
cnfg_nominal_frequency
(R/W)
5
4
(R/W)
2
0 (LSB)
forced_reference_source
XO_ edge
man_holdover
extsync_en
IP_sonsdhb
T4_op_
from_T0
master_slaveb
reversion_
mode
T4_forced_reference_source
I6_PECL
I5_LVDS
Microprocessor type
dig2_sonsdh
digital2_frequency
dig1_sonsdh
digital1_frequency
T07_PECL_LVDS
auto_BW_sel
T06_LVDS_PECL
T0_lim_int
Nominal frequency [7:0]
Nominal frequency [15:8]
[7:0] 3E
00
Holdover frequency [7:0]
[15:8] 3F
00
Holdover frequency [15:8]
cnfg_holdover_modes (R/W)
1
TO_DPLL_operating_mode
[15:8] 3D 99
cnfg_holdover_frequency
3
40
88
cnfg_DPLL_freq_limit (R/W) [7:0] 41
76
[9:8] 42
00
cnfg_interrupt_mask (R/W) [7:0] 43
00
I8 interrupt not
masked
I7 interrupt not
masked
I6 interrupt not
masked
I5 interrupt not
masked
I4 interrupt not
masked
I3 interrupt not
masked
I2 interrupt not
masked
I1 interrupt not
masked
[15:8] 44
00
Operating_
mode interrupt
not masked
Main_ref_
failed interrupt
not masked
I14 interrupt
not masked
I13 interrupt
not masked
I12 interrupt
not masked
I11 interrupt
not masked
I10 interrupt
not masked
I9 interrupt not
masked
[23:16] 45
00
Sync_ip_
T4_status
alarm interrupt interrupt not
not masked
masked
T4_inputs_
failed interrupt
not masked
AMI2_Viol
interrupt not
masked
AMI2_ LOS
interrupt not
masked
AMI1_ Viol
interrupt not
masked
AMI1_LOS
interrupt not
masked
freq_monitor_
soft_enable
freq_monitor_
hard_enable
cnfg_freq_divn (R/W)
auto_
averaging
fast_averaging read_average
Mini-holdover_mode
Holdover frequency [18:16]
(with Registers 3E and 3F above)
DPLL frequency offset limit [7:0]
DPLL frequency offset limit[9:8]
[7:0] 46
FF
[13:8] 47
3F
divn_value [7:0]
cnfg_monitors (R/W)
48
05
cnfg_freq_mon_threshold (R/W)
49
23
soft_frequency_alarm_threshold [3:0]
hard_frequency_alarm_threshold [3:0]
cnfg_current_freq_mon_
threshold (R/W)
4A
23
current soft frequency alarm threshold [3:0]
current_hard_frequency_alarm_threshold [3:0]
cnfg_registers_source_select
(R/W)
4B
00
sts_freq_measurement (R/W)
4C
00
cnfg_DPLL_soft_limit (R/W)
4D 8E
cnfg_upper_threshold_0 (R/W)
50
06
Configuration 0: Activity alarm set threshold [7:0]
cnfg_lower_threshold_0 (R/W)
51
04
Configuration 0: Activity alarm reset threshold [7:0]
Configuration 0: Activity alarm bucket size [7:0]
divn_value [13:8]
freq_mon_
clock
los_flag_
on_ TDO
ultra_fast_
switch
ext_switch
T4_T0_select
PBO_freeze
PBO_en
frequency_measurement_channel_select [3:0]
freq_measurement_value [7:0]
Freq limit
Phase loss
enable
DPLL Frequency Soft Alarm Limit [6:0] Resolution = 0.628 ppm
cnfg_bucket_size_0 (R/W)
52
08
cnfg_decay_rate_0 (R/W)
53
01
cnfg_upper_threshold_1 (R/W)
54
06
Configuration 1: Activity alarm set threshold [7:0]
Cfg 0:decay_rate [1:0]
cnfg_lower_threshold_1 (R/W)
55
04
Configuration 1: Activity alarm reset threshold [7:0]
cnfg_bucket_size_1 (R/W)
56
08
Configuration 1: Activity alarm bucket size [7:0]
cnfg_decay_rate_1 (R/W)
57
01
cnfg_upper_threshold_2 (R/W)
58
06
Configuration 2: Activity alarm set threshold [7:0]
Cfg 1:decay_rate [1:0]
cnfg_lower_threshold_2 (R/W)
59
04
Configuration 2: Activity alarm reset threshold [7:0]
cnfg_bucket_size_2 (R/W)
5A
08
Configuration 2: Activity alarm bucket size [7:0]
cnfg_decay_rate_2 (R/W)
5B
01
cnfg_upper_threshold_3 (R/W)
5C
06
cnfg_lower_threshold_3 (R/W)
5D 04
cnfg_bucket_size_3 (R/W)
5E
08
cnfg_decay_rate_3 (R/W)
5F
01
Revision 2.00/February 2003 © Semtech Corp.
Cfg 2:decay_rate [1:0]
Configuration 3: Activity alarm set threshold [7:0]
Configuration 3: Activity alarm reset threshold [7:0]
Configuration 3: Activity alarm bucket size [7:0]
Cfg 3:decay_rate [1:0]
Page 10
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ACS8530 SETS
ADVANCED COMMUNICATION
PRODUCT BRIEF
Table 7 Register Map (cont...)
Address
(hex)
Default
(hex)
Register Name
RO = Read Only
R/W = Read/Write
Data Bit
7 (MSB)
6
5
4
3
2
1
0 (LSB)
cnfg_output_frequency (R/W)
(TO1 & TO2) 60
85
output_freq_2 (TO2)
output_freq_1 (TO1)
(TO3 & TO4) 61
86
output_freq_4 (TO4)
output_freq_3 (TO3)
(TO5 & TO6) 62
8A
(TO7 to TO11) 63
F6
cnfg_T4_DPLL_frequency (R/W)
64
01
cnfg_T0_DPLL_frequency (R/W)
65
01
cnfg_T4_DPLL_bw (R/W)
66
00
cnfg_T0_DPLL_locked_bw (R/W)
67
0B
output_freq_6 (TO6)
MFrSync
enable
T4 for
measuring T0
phase
output_freq_5 (TO5)
FrSync enable
TO9 enable
TO8 enable
Auto Disable
T4 output
AMI Duty cycle
T4
SONET/SDH
selection
T4 APLL for T0
E1/DS1
output_freq_7 (TO7)
T4_DPLL_frequency
T0_DPLL_frequency
T0 Freq to T4 APLL
T4_DPLL_bandwidth [1:0]
T0_DPLL_locked_bandwidth [4:0]
cnfg_T0_DPLL_acq_bw (R/W)
69
0F
cnfg_T4_DPLL_damping (R/W)
6A
13
T4_PD2_gain_alog_8K [6:4]
cnfg_T0_DPLL_damping (R/W)
6B
13
T0_PD2_gain_alog_8K [6:4]
T0_damping [2:0]
cnfg_T4_DPLL_PD2_gain (R/W)
6C
C2
T4_PD2_gain_
enable
T4_PD2_gain_alog [6:4]
T4_PD2_gain_digital [2:0]
cnfg_T0_DPLL_PD2_gain (R/W)
6D C2
T0_PD2_gain_
enable
T0_PD2_gain_alog [6:4]
T0_PD2_gain_digital [2:0]
cnfg_phase_offset (R/W)
T0_DPLL_acquisition bandwidth [4:0]
T4_damping [2:0]
[7:0] 70
00
phase_offset_value[7:0]
[15:8] 71
00
phase_offset_value[15:8]
cnfg_PBO_phase_offset (R/W)
PBO_phase_ offset [5:0]
72
00
cnfg_phase_loss_fine_limit (R/W) 73
A2
Fine limit
Phase loss
enable (1)
No activity for
phase loss
Test Bit
Set to 1
cnfg_phase_loss_coarse_limit
(R/W)
74
85
Coarse limit
Phase loss
enable (2)
Wide range
enable
Enable Multi
Phase resp.
cnfg_phasemon (R/W)
76
06
Input noise
window enable
[7:0] 77
00
current_phase[7:0]
[15:8] 78
00
current_phase[15:8]
sts_current_phase (RO)
cnfg_phase_alarm_timeout (RO)
79
32
cnfg_sync_pulses (R/W)
7A
00
2 k/8 k out
from T4
cnfg_sync_phase (R/W)
7B
00
indep_FrSync/
MFrSync
cnfg_sync_monitor (R/W)
7C
2B
ph_offset_
ramp
cnfg_interrupt (R/W)
7D 02
cnfg_protection(R/W)
7E
85
cnfg_uPsel (R/W)
7F
02
*
Phasemon
Enable
phase_loss_fine_limit [2:0]
Phase loss coarse limit in UI pk-pk [3:0]
Phasemon
Auto PBO
Phase monitor limit [3:0]
Timeout value in 2s intervals [5:0]
Revision 2.00/February 2003 © Semtech Corp.
8 k invert
8 k pulse
enable
2 k invert
2 k pulse
enable
Sync_phase
Sync_OC-N_
rates
Sync_monitor_ limit
Sync_reference_source
GPO interrupt
enable
Interrupt
tristate
enable
Interrupt
polarity
enable
protection_value
Microprocessor type (*Default value depends on
value on UPSEL[2:0] pins)
Page 11
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ACS8530 SETS
ADVANCED COMMUNICATION
Ordering Information
PRODUCT BRIEF
Table 8 Parts List
Part Number
Description
ACS8530
SETS Synchronous Equipment Timing Source for Stratum 2/3E Systems
ACS8530 EVB
Evaluation Board and Software
Disclaimers
Life support- This product is not designed or intended for use in life support equipment, devices or systems, or other critical
applications. This product is not authorized or warranted by Semtech for such use.
Right to change- Semtech Corporation reserves the right to make changes, without notice, to this product. Customers are advised
to obtain the latest version of the relevant information before placing orders.
Compliance to relevant standards- Operation of this device is subject to the User’s implementation and design practices. It is the
responsibility of the User to ensure equipment using this device is compliant to any relevant standards.
Contacts
For Additional Information, contact the following:
Semtech Corporation Advanced Communications Products
E-mail:
[email protected]
Internet:
http://www.semtech.com
USA:
Mailing Address:
Street Address:
Tel: +1 805 498 2111,
[email protected]
P.O. Box 6097, Camarillo, CA 93011-6097
200 Flynn Road, Camarillo, CA 93012-8790
Fax: +1 805 498 3804
FAR EAST: 11F, No. 46, Lane 11, Kuang Fu North Road, Taipei, R.O.C.
Tel: +886 2 2748 3380
Fax: +886 2 2748 3390
EUROPE:
Semtech Ltd., Units 2 and 3, Park Court, Premier Way,
Abbey Park Industrial Estate, Romsey, Hampshire, SO51 9AQ
Tel: +44 (0)1794 527 600
Fax: +44 (0)1794 527 601
ISO9001
CERTIFIED
Revision 2.00/February 2003 © Semtech Corp.
Page 12
www.semtech.com