STM-S3+-8S-05.048M
更新时间:2024-09-19 05:11:11
描述:Telecom Circuit, 1-Func,
STM-S3+-8S-05.048M 概述
Telecom Circuit, 1-Func,
STM-S3+-8S-05.048M 数据手册
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PDF下载Stratum 3+
Timing Module
(STM-S3+, 3.3V)
2111 Comprehensive Drive
Aurora, Illinois 60505
Phone: 630-851-4722
Fax: 630- 851- 5040
www.conwin.com
Application
Features
The Connor-Winfield Stratum 3+ Simplified
Control Timing Module acts as a complete
system clock module for Stratum 3+ timing
applications in accordance with GR-1244-
CORE, Issue 2 and GR-253-CORE, Issue 3.
Connor-Winfield’s Stratum 3+ Timing
module helps reduce the cost of your design
by minimizing your development time and
maximizing your control of the system clock
with our simplified design.
• Dual Input
References
• Hitless Switch Over
• 8 kHz - 38.88 MHz
Sync_Out Range
• 8 kHz Independent
Output
•
3ꢀ ppb Composite
Hold Over Mode
• Fast Acquisition
Mode
• Hold Over Good
Indicator
• LOR Alarms
• Reference
Frequency Limit
Alarm
Bulletin
TM040
Page
1 of 10
Revision
P01
Date
24 Oct 02
MBATTS
Issued By
General Description
Connor-Winfield’s STM-S3+ timing module provides Acquisition mode will be initiated. Fast Acquisition mode is
Stratum 3+ synchronization for a complete system clock further described as fast start mode in GR-1244-CORE,
solution in a single module in accordance with GR-1244- Issue 3, sec 3.6.
CORE Issue 2, and GR-253-CORE Issue 3. The STM-S3+
provides a reliable network element clock reference to line The STM-S3+ may be reset by asserting a logic low signal to
cards used in TDM, PDH, SONET, and SDH application the Reset pin or cycling the power. Using the Reset pin for a
environments.Typical applications include digital cross talks, manual reset is the recommend method for resetting the
DSLAMs, ADMs, multiservice platforms, switches and module. Resetting the module by cycling the power requires
routers.
more time due to the restablization of the internal ovenized
oscillator.
The STM-S3+ meets 3ꢀ ppb Hold Over requirements over
0° – 70°C temperature range. The 3.3V power requirement
will draw a maximum of 1.6 A during an initial start-up period
and then drop to a typical current of 1.2 A during normal
operating conditions. It accepts two 8 kHz input references
and can be manufactured to supply a fixed frequency from 8
kHz to 38.88 MHz.
The STM-S3+ provides the user with non-interruptive Tri-
State capabilities. By asserting a logic high signal to the Tri-
State pin, the user is able to Tri-State all outputs. While in
Tri-State, the module continues normal operations and
accepts all normal inputs. When the module is released from
Tri-State, all output signals are valid.
The STM-S3+ offers 4 user selectable modes of operation,
Reference 1, Reference 2, Hold Over and Free Run. Mode
of operation is selected by two control pins (Table 6). The
current mode of operation is also indicated by two status
pins (Table 7). Free Run is the default mode if no control
signals are asserted on the control pins.
The STM-S3+ module provides three output frequencies.
The Sync_Out is the primary synchronized output. It is
phase locked to the input reference during normal operation
and is set to a fixed frequency when operating in Hold Over
or Free Run. Clock_Out provides a frequency output that
comes from an independent, undisciplined, free running
oscillator that is 4.6 ppm from the nominal frequency. This
output is typically used for reference frequency qualification.
The 8 kHz output is derived from the Sync_Out output.
Reference 1 mode and Reference 2 mode are the two
primary operating modes. When the module is locked to a
valid reference, any time after initial power up or reset, the
module is considered to be in the normal operating mode.
During normal operation the output frequency is phase
locked to the input reference frequency. The offset between
the input and output is dependant upon the amount of noise
that is present on the reference signal. For input tolerances,
refer to Table 4.
The STM-S3+ module provides a variety of alarm indicators
to alert the user to multiple conditions that may affect the
overall performance of their system. The LOR (Loss of
Reference) alarm indicates that the active reference has
been lost. RFL (Reference Frequency Limit) indicates that
the Sync_Out frequency is 15 ppm or more from the Free
Run frequency.
Hold Over mode provides a stable frequency that is
guaranteed to be within 0.03ꢀ ppm over the entire
temperature range for the first 24 hours after entry into Hold
Over. Hold Over is valid 101 seconds after a reference is
selected and continues to do a running average every 8
seconds for the next 104ꢀ seconds. Long-term Hold Over
values are based on a 104ꢀ second moving window
average. Hold Over values are not updated during LOR or
during Fast Acquisition mode. Hold Over values are buffered
for at least 32 seconds to allow enough time to respond to
the RFL alarm.
The Mode Alarm pin is used to indicate that the module is not
in a normal operating mode. Conditions that will cause the
Mode Alarm to go high are Hold Over, Free Run, or Fast
Acquisition Modes. See Table 8 for a full description of input
control pins and output indicator pins.
The Hold Over Good pin indicates that an initial average has
been acquired to provide a qualified Hold Over frequency.
The module requires approximately 101 seconds from any
reference switch or mode switch to a new reference to
reacquire a valid average before the indicator goes high.
Initially, entry into Hold Over prior to this will result in a Free
Run frequency. After the first Hold Over Good indication,
entry into Hold Over will be the last valid Hold Over
frequency.
Free Run is a mode of operation in which the module is not
locked to a reference and its output frequency is solely
dependent on the initial frequency setting of the internal
oscillator. The output frequency in Free Run is guaranteed
to be 4.6ppm of the nominal frequency.
The STM-S3+ meets the requirements for wander generation
and wander transfer as required by GR-1244, sections 5.3
and 5.4. Figures 4, 5 and 6 show typical results. It also
complies with phase transient requirements during
Reference Rearrangement, Entry into Hold Over, and 1 µs
transient.
Fast Acquisition mode is entered whenever Reference 1 or
2 has been selected. After a new reference has been
selected, the module uses internal filtering that limits the
frequency movement to less than 2.ꢀ ppm/sec. By 100
seconds the module switches to a slower 0.1Hz filter. While
in normal mode, if the phase error is greater than 20 µs, Fast
Preliminary Data Sheet #: TM040
Page 2 of 10
Rev: P01
Date: 10/24/02
© Copyright 2002 The Connor-Winfield Corp. All Rights Reserved Specifications subject to change without notice
Absolute Maximum Rating
Table 1
Symbol
VCC
Parameter
Minimum
-0.3
Nominal
Maximum
4.0
Units
Volts
Notes
1.0, 6.0
1.0
Power Supply Voltage
Input Voltage
VI
-0.5
5.5
Volts
Ts
Storage Temperature
-40
85
deg. C
1.0
Recommended Operating Conditions
Table 2
Symbol
Vcc
Parameter
Minimum
3.135
2.0
Nominal
3.3
Maximum
3.465
5.5
Units
Volts
Volts
Volts
Notes
6.0
Power Supply Voltage
VIH
High level input voltage - CMOS
Low level input voltage - CMOS
VIL
0
0.8
DC Characteristics
Table 3
Symbol
VOH
Parameter
Minimum
2.4
Nominal
3.3
Maximum
3.6
Units
Volts
Notes
2.0
High level output voltage,
IOH = -4.0mA, VCC = min.
VOL
Low level output voltage,
IOL = 8.0mA, VCC = max.
0.4
Volts
Specifications
Table 4
Parameter
Specifications
Notes
Frequency Range (Sync_Out)
Frequency Range (Clk_Out)
Supply Current
8 kHz - 38.88 MHz
8 kHz - 51.84 MHz
1.2 A typical, 1.6 A during warm-up (Maximum)
GR-1244-CORE 3.2.1
Timing Reference Inputs
Jitter, Wander and Phase Transient Tolerances
Wander Generation
Wander Transfer
GR-1244-CORE 4.2-4.4, GR-253-CORE 5.4.4.3.6
GR-1244-CORE 5.3, GR-253-CORE 5.4.4.3.2
GR-1244-CORE 5.4
Jitter Generation
GR-1244-CORE 5.5, GR-253-CORE 5.6.2.3
GR-1244-CORE 5.5, GR-253-CORE 5.6.2.1
GR-1244-CORE 5.6, GR-253-CORE 5.4.4.3.3
4.6 ppm over temperature range
Jitter Transfer
Phase Transients
Sync_Out (Pin #15) Free Run Accuracy
Clock_Out (Pin #18) Accuracy
Hold Over Stability
4.6 ppm over temperature range
0.012 ppm ( 5°C),
0.001 ppm
0.03ꢀ ppm (0°C - 70°C)
3.0
Inital Offset
0.001 ppm
0.035 ppm
0.003 ppm
Temperature
0.010 ppm
Drift
0.001 ppm
Maximum Hold Over History
Minimum Time for Hold Over
Pull-in/ Hold-in Range
Lock Time
104ꢀ seconds
101 seconds after a reference rearrangement
17 ppm from Free Run frequency
100 sec.
4.0
5.0
Lock Accuracy
0.01 ppm (GR-1244-CORE 2.8)
15 ppm from Free Run frequency
RFL Alarm Limit
NOTES:
3.0: Hold Over stability is the cumulative fractional frequency offset as described by
GR-1244-CORE, 5.2
1.0: Stresses beyond those listed under Absolute Maximum Rating may cause damage
to the device. Operation beyond Recommended Conditons is not implied.
4.0: Pull-in Range is the maximum frequency deviation from nominal clock rate on the
reference inputs to the timing module that can be overcome to pull into sychronization
with the reference
2.0: Logic is 3.3V CMOS
5.0: After 100 seconds at stable temperature ( 5° F)
6.0: 5.0 V module also available
Preliminary Data Sheet #: TM040
Page 3 of 10
Rev: P01
Date: 10/24/02
© Copyright 2002 The Connor-Winfield Corp. All Rights Reserved Specifications subject to change without notice
Pin Description
Table 5
Pin #
Connection
Status 0
Status 1
LOR
Description
1
2
3
4
5
6
7
Mode indicator.
Mode indicator.
Loss of Reference indicator. 1 = active reference has been lost.
Reserved for future use. Do not assert this pin.
Ground
Future Use
GND
8 kHz Output
Reset
Derived from Sync_Out.
Master reset for the module. A low pulse will reset the module. A logic low for a minimum of
1 µs is recommended to ensure a complete reset. This pin is pulled high
internally.
8
Tri-State
Tri-State control for all outputs. 1 = Hi-Z condition, 0 = Normal operation. Pin is pulled low
internally.
ꢀ
Hold Over Good
Mode Alarm
CNTL A
Indicates that the module has acquired enough data to provide an average Hold Over value.
10
11
12
13
14
15
16
17
18
Alarm indicator output. 1 = Alarm condition, 0 = Normal operation.
Mode control input. Pin is pulled low internally.
CNTL B
Mode control input. Pin is pulled low internally.
RFL
Reference frequency limit alarm for the phase locked loop. 1= Unit is 15 ppm from Free Run freq.
GND
Ground
Sync_Out
Future Use
GND
System clock output
Reserved for future use. Do not assert this pin
Ground
Clock_Out
An independent, Stratum 3 clock output with the required 4.6 ppm accuracy. May be used as
general purpose clock
1ꢀ
20
21
22
23
24
Future Use
GND
Reserved for future use. Do not assert this pin
Ground
External Reference 2
GND
External reference #2 input
Ground
External Reference 1
+3.3 VDC
External reference #1 input
+3.3 Volt DC supply
Control Inputs
Table 6
Status Outputs
Table 7
CNTL B
CTNL A
Mode Selected
Free Run
Status 1
Status 0
Mode
0
0
1
1
0
1
0
1
0
0
1
1
0
1
0
1
Free Run
Reference 1
Reference 2
Hold Over
Reference 1
Reference 2
Hold Over
Preliminary Data Sheet #: TM040
Page 4 of 10
Rev: P01
Date: 10/24/02
© Copyright 2002 The Connor-Winfield Corp. All Rights Reserved Specifications subject to change without notice
Pin Assignment
Figure 1
24
23
22
21
20
19
18
17
16
15
14
13
1
2
+3.3Vdc
Status 0
Status 1
LOR
External Reference 1
GND
3
4
External Reference 2
GND
Future Use
GND
5
6
Future Use
Clock_Out
GND
Future Use
Sync_Out
GND
8 kHz output
Reset
7
8
Tri-State
Hold Over Good
Mode Alarm
CNTL A
9
10
11
12
RFL
CNTL B
Typical Application Setup
Figure 2
3.3 Vdc
Power Supply
+3.3 Vdc
Status 0
Status 1
LOR
External Reference 1
GND
Network Timing
Reference Input
eg. BITS
External Reference 2
GND
Future Use
GND
System Control
State Machine
8 kHz output
Future Use
Clock_Out
Independent
Free Run
Reset
GND
Tri-State
Future Use
Sync_Out
Hold Over Good
Mode Alarm
CNTL A
System
Clock
GND
RFL
CNTL B
Preliminary Data Sheet #: TM040
Page 5 of 10
Rev: P01
Date: 10/24/02
© Copyright 2002 The Connor-Winfield Corp. All Rights Reserved Specifications subject to change without notice
Functional Truth Table
Table 8
CNTLB CNTLA
Mode
Status1Status0 Alarm RFL
LOR
Condition
0
0
0
0
0
0
0
1
1
1
Free Run
0
0
0
0
0
0
0
1
1
1
1
1
0
1
0
0
1
0
0
1
0
0
0
0
0
Free Run
Reference #1
Reference #1
Reference #1
Normal Operation
Unit is in Fast Acquire mode
Output freq. is 15 ppm or more from Free
Run mode freq.
0
1
Reference #1
0
1
0
0
1
Selected reference signal is not detected
and unit is in pseudo-Hold Over*
1
1
1
0
0
0
Reference #2
Reference #2
Reference #2
1
1
1
0
0
0
0
1
0
0
0
1
0
0
0
Normal Operation
Unit is in Fast Acquire mode
Output freq. is 15 ppm or more from
Free Run mode freq.
1
0
Reference #2
1
0
0
0
1
Selected reference signal is not detected
and unit is in pseudo-Hold Over*
1
1
1
1
Hold Over
Hold Over
1
1
1
1
1
1
0
1
0
0
*Psuedo-Hold Over is a condition when the module is no longer tracking a reference and is holding the last output that was sent to
the Sync_Out pin. Variations in the output frequency are due only to the drift of the OCXO.
Ordering Information
STM-S3+ -L- (Input Reference Frequency)(Clock_Out Frequency)-(Sync_Out)
Nothing = 5V
L = 3.3V
8= 8 kHz
S= Other
N= No output
2= 2.048 MHz
5= 51.84 MHz
8= 8 kHz
ꢀ= 1ꢀ.44 MHz
S= Other
02.048M = 2.048MHz
016.384M = 16.384 MHz
032.768M = 32.768 MHz
038.88 M = 38.88 MHz
008.00K = 8 kHz
Example: MSTM-S3+ -L-88-008.00K
Preliminary Data Sheet #: TM040
Page 6 of 10
Rev: P01
Date: 10/24/02
© Copyright 2002 The Connor-Winfield Corp. All Rights Reserved Specifications subject to change without notice
Functional Block Diagram
Figure 3
Fast Acquire
Free Run
Hold Over
CNTLA
CNTLB
Mode Alarm
RESET
Status 1
LOR
Status 2
REF #1
REF #2
DSP
RFL
Hold Over Good
Sync_Out
DDS
OCXO
1/N
Voltage
Regulation
8 kHz Output
Clk_Out
TCXO
Preliminary Data Sheet #: TM040
Page 7 of 10
Rev: P01
Date: 10/24/02
© Copyright 2002 The Connor-Winfield Corp. All Rights Reserved Specifications subject to change without notice
Loss of Reference Timing
Figure 4
RFL Alarm Timing
Figure 5
RFL Limit High
Frequency
Sync_Out
(Nominal Frequency)
External
Reference
Input
RFL Limit Low
Frequency
RFL Alarm
Alarm
∆
t
tAon
tAoff
0 < ∆t < 2.125 msec
*The DDS is updated only when the output changes level. The maximum
update rate is 8 kHz
2 msec < tAon < 6.125 msec
0 msec < tAoff < 2.125 msec
Mode Switch Timing
Figure 6
Mounting Clearance Dimensions
Figure 7
.020" MAX.
Change in
Control Inputs
.020"
Operational Mode
Indicator
∆
tm
.030"
PIN LAND
2 msec <∆tm < 4.125 msec
ALL SOLDER AND/OR WIRE TAGS
SHALL NOT EXTEND MORE THAN .020"
BELOW PC BOARD BOTTOM SURFACE
Preliminary Data Sheet #: TM040
Page 8 of 10
Rev: P01
Date: 10/24/02
© Copyright 2002 The Connor-Winfield Corp. All Rights Reserved Specifications subject to change without notice
Package Dimensions
Figure 8
Preliminary Data Sheet #: TM040
Page 9 of 10
Rev: P01
Date: 10/24/02
© Copyright 2002 The Connor-Winfield Corp. All Rights Reserved Specifications subject to change without notice
2111 Comprehensive Drive
Aurora, Illinois 60505
Phone: 630-851-4722
Fax: 630- 851- 5040
www.conwin.com
Revision #
P00
Revision DateNotes
7/26/02
Preliminary informational release
Added ordering information
P01
10/24/02
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