ICS M1040-11I155.5200

Preliminary Information
Integrated
Circuit
Systems, Inc.
M1040
VCSO BASED CLOCK PLL WITH AUTOSWITCH
The M1040 is a VCSO (Voltage Controlled SAW
Oscillator) based clock generator
PLL designed for clock protection,
frequency translation and jitter
attenuation in OC-12/48 class optical
networking systems. It features dual
differential inputs with two modes of
input selection: manual and
automatic upon clock failure. The clock multiplication
ratios and output divider ratio are pin selectable. This
device provides two outputs. External loop components
allow the tailoring of PLL loop response.
MR_SEL1
MR_SEL0
REF_ACK
LOL
NBW
VCC
DNC
DNC
DNC
28
29
30
31
32
33
34
35
36
P_SEL
INIT
nFOUT0
FOUT0
GND
nFOUT1
FOUT1
VCC
GND
18
17
16
15
14
13
12
11
10
M1040
(Top View)
1
2
3
4
5
6
7
8
9
FEATURES
MR_SEL2
GND
AUTO
DIF_REF0
nDIF_REF0
REF_SEL
DIF_REF1
nDIF_REF1
VCC
PIN ASSIGNMENT (9 x 9 mm SMT)
27
26
25
24
23
22
21
20
19
GENERAL DESCRIPTION
GND
GND
GND
OP_IN
nOP_OUT
nVC
VC
OP_OUT
nOP_IN
◆ Integrated SAW (surface acoustic wave) delay line;
low phase jitter of < 0.5ps rms, typical (12kHz to
20MHz)
◆ Output frequencies of 62.5 to 175 MHz *; Two differential LVPECL outputs (CML, LVDS options available)
Figure 1: Pin Assignment
◆ Loss of Lock (LOL) indicator output
◆ Narrow Bandwidth control input (NBW pin);
Initialization (INIT) input overrides NBW at power-up
◆ Dual reference clock inputs support LVDS, LVPECL,
LVCMOS, LVTTL
◆ AutoSwitch (AUTO pin) - automatic (non-revertive)
reference clock reselection upon clock failure; Hitless
Switching (HS), Phase Build-out (PBO) options enable
SONET (GR-253)/SDH (G.813) MTIE/TDEV compliance
◆ Acknowledge pin (REF_ACK pin) indicates the actively
selected reference input
◆ Industrial temperature available
◆ Single 3.3V power supply
◆ Small 9 x 9 mm SMT (surface mount) package
Example I/O Clock Frequency Combinations
Using M1040-11-155.5200
PLL Ratio
Input Reference
Clock (MHz)
(Pin Selectable)
19.44
77.76
155.52
622.08
8
2
1
0.25
Output Clock
(MHz)
(Pin Selectable)
155.52
or
77.76
Table 1: Example I/O Clock Frequency Combinations
* Specify VCSO center frequency at time of order.
SIMPLIFIED BLOCK DIAGRAM
Loop Filter
M1040
NBW
PLL
Phase
Detector
MUX
DIF_REF0
nDIF_REF0
0
DIF_REF1
nDIF_REF1
1
R Div
VCSO
REF_ACK
REF_SEL
0
1
AUTO
M Divider
LOL
Phase
Detector
Auto
Ref Sel
INIT
LOL
MR_SEL2:0
3
FOUT0
nFOUT0
P Divider
M / R Divider
(1 or 2)
LUT
FOUT1
nFOUT1
P_SEL
Figure 2: Simplified Block Diagram
M1040 Datasheet Rev 0.1
Revised 11Nov2003
M1040 VCSO Based Clock PLL with AutoSwitch
Integrated Circuit Systems, Inc.
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M1040
Integrated
Circuit
Systems, Inc.
VCSO BASED CLOCK PLL WITH AUTOSWITCH
Preliminary Information
PIN DESCRIPTIONS
Number
1, 2, 3, 10, 14, 26
4
9
5
8
6
7
Name
GND
OP_IN
nOP_IN
nOP_OUT
OP_OUT
nVC
VC
11, 19, 33
VCC
12
13
15
16
FOUT1
nFOUT1
FOUT0
nFOUT0
17
INIT
18
P_SEL
Internal pull-down1
20
nDIF_REF1
Biased to Vcc/2 2
21
DIF_REF1
22
REF_SEL
23
nDIF_REF0
24
DIF_REF0
25
AUTO
Input
Internal pull-down resistor1
27
28
29
MR_SEL2
MR_SEL1
MR_SEL0
Input
Internal pull-UP resistor1
30
REF_ACK
Output
31
LOL
Output
32
NBW
Input
34, 35, 36
DNC
Note 1:
Note 2:
Note 3:
Note 4:
I/O
Configuration
Ground
Description
Power supply ground connections.
Input
External loop filter connections. See Figure 5,
External Loop Filter, on pg. 8.
Output
Input
Power
Power supply connection, connect to +3.3V.
Output
No internal terminator
Clock output pair 1. Differential LVPECL.
Output
No internal terminator
Clock output pair 0. Differential LVPECL.
Input
Internal pull-UP resistor1
Input
Internal pull-down resistor1
Input
Internal pull-down resistor1
Biased to Vcc/2 3
Input
Internal pull-down resistor1
Internal pull-UP resistor1
Power-on Initialization; LVCMOS/LVTTL:
Logic 1 allows device to enter narrow mode if
selected (in addition must have 8 LOL=0 counts)
Logic 0 forced device into wide bandwidth mode.
Post-PLL , P divider selection. LVCMOS/LVTTL.
See Table 4, P Divider Selector Values
and Frequencies, on pg. 3.
Reference Differential LVPECL/ LVDS
clock input Differential LVPECL/ LVDS, or single
pair 1.
ended LVCMOS/ LVTTL
Reference clock input selection. LVCMOS/LVTTL.
Logic 1 selects DIF_REF1/nDIF_REF1 inputs
Logic 0 selects DIF_REF0/nDIF_REF0 inputs
Reference Differential LVPECL/ LVDS
clock input Differential LVPECL/ LVDS, or single
pair 0.
ended LVCMOS/ LVTTL
Automatic/manual reselection mode for clock input:
Logic 1 automatic reselection upon clock failure
(non-revertive)
Logic 0 manual selection only (using REF_SEL)
M and R divider value selection. LVCMOS/ LVTTL.
See Table 3, M and R Divider Look-Up Tables (LUT)
on pg. 3.
Reference Acknowledgement pin for input mux state;
outputs the currently selected reference input pair:
Logic 1 indicates nDIF_REF1, DIF_REF1
Logic 0 indicates nDIF_REF0, DIF_REF0
Loss of Lock indicator output. 4
Logic 1 indicates loss of lock.
Logic 0 indicates locked condition.
Narrow Bandwidth enable. LVCMOS/LVTTL:
Logic 1 - Narrow loop bandwidth, RIN = 2100kΩ.
Logic 0 - Wide bandwidth, RIN = 100kΩ.
Do Not Connect.
Table 2: Pin Descriptions
For typical values of internal pull-down and pull-up resistors, see DC Characteristics on pg. 10.
Biased to Vcc/2, with 50kΩ to Vcc and 50kΩ to ground. Float if using DIF_REF1 as LVCMOS input. See DC Characteristics on pg. 10.
Biased to Vcc/2, with 50kΩ to Vcc and 50kΩ to ground. Float if using DIF_REF0 as LVCMOS input. See DC Characteristics on pg. 10.
See LVCMOS Outputs in DC Characteristics on pg. 10.
M1040 Datasheet Rev 0.1
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M1040
Integrated
Circuit
Systems, Inc.
VCSO BASED CLOCK PLL WITH AUTOSWITCH
Preliminary Information
DETAILED BLOCK DIAGRAM
R LOOP
C LOOP
R POST
External
Loop Filter
Components
C POST
C POST
R LOOP
OP_IN
M1040
nOP_IN
C LOOP
R POST
OP_OUT
nOP_OUT
nVC
VC
NBW
PLL
Phase
Detector
MUX
DIF_REF0
nDIF_REF0
0
DIF_REF1
nDIF_REF1
1
R IN
Divider
R IN
SAW Delay Line
Phase
Locked
Loop
(PLL)
R
Loop Filter
Amplifier
Phase
Shifter
VCSO
REF_ACK
REF_SEL
M Divider
0
1
LOL
Phase
Detector
AUTO
Auto
Ref Sel
INIT
LOL
MR_SEL2:0
3
FOUT0
nFOUT0
P Divider
M / R Divider
FOUT1
nFOUT1
LUT
P_SEL
Figure 3: Detailed Block Diagram
PLL DIVIDER SELECTION TABLES
General Guidelines for M and R Divider Selection
M and R Divider Look-Up Tables (LUT)
General guidelines for M/R divider selection (see
following pages for more detail):
The MR_SEL2:0 pins select the feedback and reference
divider values M and R to enable adjustment of loop
bandwidth and jitter tolerance. The look-up is defined in
Table 3.
• A lower phase detector frequency should be used for
M1040 M/R Divider LUT
MR_SEL3:0 M Div R Div
Phase Det.
Total
Fin for
Freq. for
PLL
155.52MHz 155.52MHz
Ratio VCSO (MHz) VCSO (MHz)
000
8
1
8
19.44
19.44
001
64
8
8
19.44
2.43
010
2
1
2
77.76
77.76
011
16
8
2
77.76
9.72
100
1
1
1
155.52
155.52
101
8
8
1
155.52
19.44
N/A
N/A
N/A
622.08
77.76
110
111
Test Mode1
2
8
0.25
•
Post-PLL Divider
Table 3: M1040 M/R Divider LUT
Note 1: Factory test mode; do not use.
•
loop timing applications to assure PLL tracking,
especially during GR-253 jitter tolerance testing. The
recommended maximum phase detector frequency
for loop timing mode is 19.44MHz. The LOL pin should
not be used during loop timing mode.
When LOL is to be used for system health monitoring,
the phase detector frequency should be 5MHz or
greater. Low phase detector frequencies make LOL
overly sensitive, and higher phase detector
frequencies make LOL less sensitive.
The preceding guideline also applies when using the
AutoSwitch Mode, since AutoSwitch uses the LOL
output for clock fault detection.
The M1040 also features a post-PLL (P) divider for the
output clocks. It divides the VCSO frequency to produce
one of two selectable output frequencies (1/2 or 1/1 of
the VCSO frequency). That selected frequency appears
on both clock output pairs. The P_SEL pin selects the
value for the P divider.
Table 3 provides example Fin and phase detector
frequencies with 155.52MHz VCSO devices
(e.g., M1040-11-155.5200). See “Ordering Information”
on pg. 12.
P_SEL
P Value
1
0
2
1
M1040-11-155.52
Output Frequency
(MHz)
77.76
155.52
Table 4: P Divider Selector Values and Frequencies
M1040 Datasheet Rev 0.1
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M1040
Integrated
Circuit
Systems, Inc.
VCSO BASED CLOCK PLL WITH AUTOSWITCH
Preliminary Information
FUNCTIONAL DESCRIPTION
Input Reference Clocks
The M1040 is a PLL (Phase Locked Loop) based clock
generator that generates two output clocks synchronized to one of two selectable input reference clocks.
An internal high “Q” SAW delay line provides a low jitter
clock output.
Two clock reference inputs and a selection mux are
provided. Either reference clock input can accept a
differential clock signal (such as LVPECL or LVDS) or
a single-ended clock input (LVCMOS or LVTTL on the
non-inverting input).
A pin-selected look-up table is used to select the PLL
feedback divider (M Div) and reference divider (R Div)
as shown in Table 3 on pg. 3. The look-up table provides
flexibility in both the overall frequency multiplication
ratio (total PLL ratio) and phase detector frequency.
External loop filter component values influence the PLL
bandwidth, which is used to optimize jitter attenuation
characteristics.
The device features dual differential inputs with two
input selection modes: manual and automatic upon
clock failure. (The differential inputs are internally
configured for easy single-ended operation.)
The M1040 also includes: a Loss of Lock (LOL) indicator,
a reference mux state acknowledge pin (REF_ACK), a
Narrow Bandwidth control input pin (NBW pin), and a
Power-on Initialization (INIT) input (which overrides
NBW=0 to facilitate acquisition of phase lock).
A single-ended reference clock on the unselected
reference input can cause an increase in output
clock jitter. For this reason, differential reference
inputs are preferred; interference from a differential
input on the non-selected input is minimal.
Implementation of single-ended input has been facilitated by biasing nDIF_REF0 and nDEF_REF1 to Vcc/2, with
50kΩ to Vcc and 50kΩ to ground. Figure 4 shows the
input clock structure and how it is used with either
LVCMOS / LVTTL inputs or a DC- coupled LVPECL
clock.
LVCMOS/
LVTTL
50k Ω
VCC
MUX
50k Ω
0
X
VCC
50kΩ
1
127 Ω
VCC
VCC
An automatic input reselection feature, or “AutoSwitch”
is also included in the M1040. When the AutoSwitch
mode is enabled, the device will automatically switch to
the other reference clock input when the currently
selected reference clock fails. Reference selection is
non-revertive, meaning that only one reference
reselection will be made each time that AutoSwitch is
re-enabled.
Differential Inputs
In addition to the AutoSwitch feature, Hitless Switching
and Phase Build-out options can be ordered with the
device. The Hitless Switching and Phase Build-out
options help assure SONET/SDH MTIE and TDEV
compliance during either a manual or automatic input
reference reselection.
Differential LVPECL inputs are connected to both
reference input pins in the usual manner. The external
load termination resistors shown in Figure 4 (the 127Ω
and 82Ω resistors) will work for both AC and DC
coupled LVPECL reference clock lines. These provide
the 50Ω load termination and the VTT bias voltage.
Hitless Switching (HS) provides a controlled output
clock phase change during a reference clock
reselection. HS is triggered by a Loss of Lock detection
by the PLL.
Single-ended Inputs
82 Ω
LVPECL
50k Ω
127 Ω
50kΩ
82 Ω
50kΩ
REF_SEL
Figure 4: Input Reference Clocks
Single-ended inputs (LVCMOS or LVTTL) are
connected to the non-inverting reference input pin
(DIF_REF0 or DIF_REF1). The inverting reference input pin
(nDIF_REF0 or nDIF_REF1) must be left unconnected.
In single-ended operation, when the unused inverting
input pin (nDIF_REF0 or nDEF_REF1) is left floating (not
connected), the input will self-bias at VCC/2.
M1040 Datasheet Rev 0.1
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M1040
Integrated
Circuit
Systems, Inc.
VCSO BASED CLOCK PLL WITH AUTOSWITCH
Preliminary Information
PLL Operation
Loss of Lock Indicator Output Pin
The M1040 is a complete clock PLL. It uses a phase
detector and configurable dividers to synchronize the
output of the VCSO with the selected reference clock.
Under normal device operation, when the PLL is locked,
the LOL Phase Detector drives LOL to logic 0. Under
circumstances when the VCSO cannot lock to the input
(as measured by a greater than 4 ns discrepancy
between the feedback and reference clock rising edges
at the LOL Phase Detector) the LOL output goes to logic
1. The LOL pin will return back to logic 0 when the phase
detector error is less than 2 ns. The loss of lock
indicator is a low current LVCMOS output.
The “M” divider divides the VCSO output frequency,
feeding the result into the plus input of the phase
detector. The output of the “R” divider is fed into the
minus input of the phase detector. The phase detector
compares its two inputs. The phase detector output,
filtered externally, causes the VCSO to increase or
decrease in speed as needed to phase- and
frequency-lock the VCSO to the reference input.
The value of the M divider directly affects closed loop
bandwidth.
The relationship between the nominal VCSO center
frequency (Fvcso), the M divider, the R divider, and the
input reference frequency (Fin) is:
M
Fvcso = Fin × ---R
For the available M divider and R divider look-up table
combinations, Tables 3 and 4 on pg. 3 list the Total PLL
Ratio as well as Fin when using the M1040-11-155.5200.
(See “Ordering Information”, pg. 12.)
Due to the narrow tuning range of the VCSO
(+200ppm), appropriate selection of all of the following
are required for the PLL be able to lock: VCSO center
frequency, input frequency, and divider selections.
Guidelines Using LOL
As described, the LOL pin indicates when the PLL is
out-of-lock with the input reference. The LOL condition
is also used by the AutoSwitch circuit to detect a lost
reference, as described in following sections. LOL is
also used by the Hitless Switching and Phase Build-out
functions (optional device features). To ensure reliable
operation of LOL and guard against false out-of-lock
indications, the following conditions should be met:
• The phase detector frequency should be no less than
•
Post-PLL Divider
The M1040 features a post-PLL (P) divider. By using
the P Divider, the device’s output frequency (Fout) can
be the VCSO center frequency (Fvcso) or 1/2 Fvcso.
The P_SEL pin selects the value for the P divider: logic 1
sets P to 2, logic 0 sets P to 1. (See Table 5 on pg. 6.)
When the P divider is included, the complete relationship for the output frequency (Fout) is defined as:
M
Fvcso = Fin × ----------------Fout = ------------------P
R× P
M1040 Datasheet Rev 0.1
Integrated Circuit Systems, Inc.
5MHz, and preferably it should be 10MHz or greater.
Phase detector frequency is defined by Fin / R.
A higher phase detector frequency will result in lower
phase error and less chance of false triggering the
LOL phase detector. Refer to Tables 3 and 4 on pg. 3
for phase detector frequency when using the
M1040-11-155.5200.
The input reference should have an intrinsic jitter of
less than 1 ns pk-pk. If reference jitter is greater than
1 ns pk-pk, the LOL circuit might falsely trigger. Due
to this limitation, the LOL circuit should not be used in
loop timing mode, nor should it be used with a noisy
reference clock. Likewise, the AutoSwitch, Hitless
Switching, or Phase Build-out features should not be
used in loop timing mode or with a noisy reference
clock, since these features depend on LOL.
Reference Acknowledgement (REF_ACK) Output
The REF_ACK (reference acknowledgement) pin outputs
the value of the reference clock input that is routed to
the phase detector. Logic 1 indicates input pair 1
(nDIF_REF1, DIF_REF1); logic 0 indicates input pair 0
(nDIF_REF0, DIF_REF0). The REF_ACK indicator is an
LVCMOS output.
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M1040
Integrated
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VCSO BASED CLOCK PLL WITH AUTOSWITCH
Preliminary Information
AutoSwitch (AUTO) Reference Clock Reselection
This device offers an automatic reference clock
reselection feature for switching input reference clocks
upon a reference clock failure. With the AUTO input pin
set to high and the LOL output low, the device is placed
into automatic reselection (AutoSwitch) mode. Once in
AutoSwitch mode, when LOL then goes high (due to a
reference clock fault), the input clock reference is
automatically reselected internally, as indicated by the
state change of the REF_ACK output. Automatic clock
reselection is made only once (it is non-revertive).
Re-arming of automatic mode requires placing the
device into manual selection (Manual Select) mode
(AUTO pin low) before returning to AutoSwitch mode
(AUTO pin high).
Using the AutoSwitch Feature
See alsoTable 5, Example AutoSwitch Sequence.
In application, the system is powered up with the device
in Manual Select mode (AUTO pin is set low), allowing
sufficient time for the reference clock and device PLL to
settle. The REF_SEL input selects the reference clock to
be used in Manual Select mode and the initial reference
clock used in AutoSwitch mode. The REF_SEL input state
must be maintained when switching to AutoSwitch
mode (AUTO pin high) and must still be maintained until a
reference fault occurs.
Once a reference fault occurs, the LOL output goes high
and the input reference is automatically reselected. The
REF_ACK output always indicates the reference selection
status and the LOL output always indicates the PLL lock
status.
A successful automatic reselection is indicated by a
change of state of the REF_ACK output and a momentary
level high of the LOL output (minimum high time is 10
ns).
If an automatic reselection is made to a non-valid
reference clock (one to which the PLL cannot lock),
the REF_ACK output will change state but the LOL
output will remain high.
No further automatic reselection is made; only one
reselection is made each time the AutoSwitch mode is
armed. AutoSwitch mode is re-armed by placing the
device into Manual Select mode (AUTO pin low) and then
into AutoSwitch mode again (AUTO pin high).
Following an automatic reselection and prior to
selecting Manual Select mode (AUTO pin low), the
REF_SEL pin has no control of reference selection.
To prevent an unintential reference reselection,
AutoSwitch mode must not be re-enabled until the
desired state of the REF_SEL pin is set and the LOL output
is low. It is recommended to delay the re-arming of
AutoSwitch mode, following an automatic reselection,
to ensure the PLL is fully locked on the new reference.
In most system configurations, where loop bandwidth is
in the range of 100-1000 Hz and damping factor below
10, a delay of 500 ms should be sufficient. Until the PLL
is fully locked intermittent LOL pulses may occur.
Example AutoSwitch Sequence
0 = Low; 1 = High. Example with REF_SEL initially set to 0 (i.e., DIF_REF0 selected)
REF_SEL Selected REF_ACK AUTO LOL Conditions
Input
Clock Input
Output
Input
Output
0
DIF_REF0
0
0
1
0
DIF_REF0
0
0
-0-
0
DIF_REF0
0
-1-
0
Initialization
Device power-up. Manual Select mode. DIF_REF0 input selected reference, not yet locked to.
LOL to 0: Device locked to reference (may get intermittent LOL pulses until fully locked).
AUTO set to 1: Device placed in AutoSwitch mode (with DIF_REF0 as initial reference clock).
Operation & Activation
Normal operation with AutoSwitch mode armed, with DIF_REF0 as initial reference clock.
0
DIF_REF0
0
1
0
0
0
DIF_REF0
-DIF_REF1-
0
-1-
1
1
-11
LOL to 1: Clock fault on DIF_REF0, loss of lock indicated by LOL pin, ...
... and immediate automatic reselection to DIF_REF1 (indicated by REF_ACK pin).
0
DIF_REF1
1
1
-0-
LOL to 0: Device locks to DIF_REF1 (assuming valid clock on DIF_REF1).
-1-
DIF_REF1
1
1
0
REF_SEL set to 1: Prepares for Manual Selection of DIF_REF1 before then re-arming AutoSwitch.
1
DIF_REF1
1
-0-
0
AUTO set to 0: Manual Select mode entered briefly, manually selecting DIF_REF1 as reference.
1
DIF_REF1
1
-1-
0
AUTO set to 1: Device is placed in AutoSwitch mode (delay recommended to ensure device fully
locked), re-initializing AutoSwitch with DIF_REF1 now specified as the initial reference clock.
Re-initialization
Table 5: Example AutoSwitch Sequence
M1040 Datasheet Rev 0.1
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M1040
Integrated
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Systems, Inc.
VCSO BASED CLOCK PLL WITH AUTOSWITCH
Preliminary Information
Optional Hitless Switching and Phase Build-out
HS/PBO Triggers
The M1040 is available with a Hitless Switching feature
that is enabled during device manufacturing.
In addition, a Phase Build-out feature is also offered.
These features are offered as device options and are
specified by device order code. Refer to Section ,
“Ordering Information” on pg. 12.
The HS function (or the combined HS/PBO function)
is armed after the device locks to the input clock reference. Once armed, HS is triggered by the occurance of
a Loss of Lock condition. This would typically occur as a
consequence of a clock reference failure, a clock failure
upstream to the M1040, or a M1040 clock reference
mux reselection.
The Hitless Switching feature (with or without Phase
Build-out) is designed for applications where switching
occurs between two stable system reference clocks. It
should not be used in loop timing applications, or when
reference clock jitter is greater than 1 ns pk-pk. Hitless
Switching is triggered by the LOL circuit, which is
activated by a 4 ns phase transient. This magnitude of
phase transient can generated by the CDR (Clock &
Data Recovery unit) in loop timing mode, especially
during a system jitter tolerance test. It can also be
generated by some types of Stratum clock DPLLs
(digital PLL), especially those that do not include a post
de-jitter APLL (analog PLL).
When the Hitless Switching feature is enabled, it is
always triggered by LOL, whether in AutoSwitch mode
(AUTO pin high) or Select mode (AUTO pin low). For
example, in Manual mode, the Hitless Switching feature
operates when LOL goes high even if there is no
reselection of the input mux. This enables the use of an
upstream clock mux (such as on the host card), while
still providing MTIE compliance when readjusting to the
resultant phase change.
When the M1040 is operating in wide bandwidth mode
(NBW=0), the optional Hitless Switching function puts the
device into narrow bandwidth mode when activated.
This allows the PLL to lock the new input clock phase
gradually. With proper configuration of the external loop
filter, the output clock complies with MTIE and TDEV
specifications for GR-253 (SONET) and ITU G.813
(SDH) during input reference clock changes.
The optional proprietary Phase Build-out (PBO)
function enables the PLL to absorb most of the phase
change of the input clock. The PBO function selects a
new VCSO clock edge for the PLL Phase Detector
feedback clock, selecting the edge closest in phase to
the new input clock phase. This reduces re-lock time,
the generation of wander, and extra output clock cycles.
The Hitless Switching and Phase Build-out functions
are triggered by the LOL circuit. For proper operation,
a low phase detector frequency must be avoided. See
Section , “Guidelines Using LOL” on pg. 5 for
information regarding the phase detector frequency.
M1040 Datasheet Rev 0.1
Integrated Circuit Systems, Inc.
When pin AUTO = 1 (automatic reference
reselection mode) HS is used in conjunction with
input reselection. When AUTO = 0 (manual mode),
HS will still occur upon an input phase transient,
however the clock input is not reselected (this
enables hitless switching when using an external
MUX for clock selection).
HS/PBO Operation
Once triggered, the following HS/PBO sequence
occurs:
1. The HS function disables the PLL Phase Detector
and puts the device into NBW (narrow bandwidth)
mode. The internal resistor Rin is changed to
2100kΩ . See the Narrow Loop Bandwidth Control
Pin (NBW Pin) on pg. 7.
2. If included, the PBO function adds to (builds out) the
phase in the clock feedback path (in VCSO clock
cycle increments) to align the feedback clock with
the (new) reference clock input phase.
3. The PLL Phase Detector is enabled, allowing the
PLL to re-lock.
4. Once the PLL Phase Detector feedback and input
clocks are locked to within 2 ns for eight consecutive
cycles, a timer (WBW timer) for resuming wide
bandwidth (in 175 ns) is started.
5. When the WBW timer times out, the device reverts
to wide loop bandwidth mode (i.e., Rin is returned to
100kΩ) and the HS/PBO function is re-armed.
Narrow Loop Bandwidth Control Pin (NBW Pin)
A Narrow Loop Bandwidth control pin (NBW pin) is
included to adjust the PLL loop bandwidth. In wide
bandwidth mode (NBW=0), the internal resistor Rin is
100kΩ . With the NBW pin asserted, the internal resistor
Rin is changed to 2100kΩ . This lowers the loop
bandwidth by a factor of about 21 (approximately 2100 /
100) and lowers the damping factor by a factor of about
4.6 (the square root of 21), assuming the same loop
filter components.
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M1040
Integrated
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VCSO BASED CLOCK PLL WITH AUTOSWITCH
Preliminary Information
Power-Up Initialization Function (INIT Pin)
The initialization function provides a short-term override
of the narrow bandwidth mode when the device is
powered up in order to facilitate phase locking.
Because of the differential signal path design, the
implementation consists of two identical
complementary RC filters as shown in
Figure 5.
RLOOP
When INIT is set to logic 1, initialization is enabled. With
NBW set to logic 1 (narrow bandwidth mode), the
initialization function puts the PLL into wide bandwidth
mode until eight consecutive phase detector cycles
occur without a single LOL event. Once the eight valid
PLL locked states have occurred, the PLL bandwidth is
automatically reduced to narrow bandwidth mode.
CLOOP
RPOST
CPOST
CPOST
RLOOP
OP_IN
When INIT is logic 0, the device is forced into wide
bandwidth mode unconditionally.
nOP_IN
4
RPOST
CLOOP
OP_OUT
9
nOP_OUT
8
nVC
5
VC
6
7
Figure 5: External Loop Filter
External Loop Filter
The M1040 requires the use of an external loop filter
components. These are connected to the provided filter
pins (see Figure 5).
PLL bandwidth is affected by the total “M” (feedback
divider) value, loop filter component values, and other
device parameters. See Table 6, Example External
Loop Filter Component Values, below.
PLL Simulator Tool Available
A free PC software utility is available on the ICS website
(www.icst.com). The M2000 Timing Modules PLL
Simulator is a downloadable application that simulates
PLL jitter and wander transfer characteristics. This
enables the user to set appropriate external loop
component values in a given application.
For guidance on device or loop filter implementation, contact CMBU (Commercial Business Unit)
Product Applications at (508) 852-5400.
Example External Loop Filter Component Values1
for M1040-yz-155.5200
VCSO Parameters: KVCO = 200kHz/V, RIN = 100kΩ (pin NBW = 0), VCSO Bandwidth = 700kHz.
FREF
(MHz)
Device Configuration
Example External Loop Filter Comp. Values
FVCSO MR_SEL2:0 MDiv NBW RLOOP
CLOOP
RPOST
CPOST
(MHz)
PLL Loop
Bandwidth
Damping Passband
Factor Peaking (dB)
10µF
82kΩ
1000pF
315Hz
5.4
0.07
3.9kΩ
10µF
33kΩ
1000pF
715Hz
6.2
0.05
12kΩ
2.2µF
82kΩ
1000pF
275Hz
3.1
0.20
2.7kΩ
10µF
47kΩ
470pF
980Hz
6.0
0.05
5.6kΩ
4.7µF
82kΩ
1000pF
260Hz
3.0
0.20
19.44 2
155.52
000
8
0
6.8kΩ
3
155.52
010
2
0
77.76 2
155.52
0 1 1 16
0
155.52 3
155.52
100
1
0
155.52 2
155.52
101
8
0
77.76
Nominal Performance Using These Values
Table 6: Example External Loop Filter Component Values
Note 1: KVCO , VCSO Bandwidth, M Divider Value, and External Loop Filter Component Values determine Loop Bandwidth, Damping Factor,
and Passband Peaking. For PLL Simulator software, go to www.icst.com.
Note 2: Optimal for system clock filtering.
Note 3: Optimal for loop timing mode (LOL or Hitless Switching should not be used).
M1040 Datasheet Rev 0.1
Integrated Circuit Systems, Inc.
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M1040
Integrated
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Systems, Inc.
VCSO BASED CLOCK PLL WITH AUTOSWITCH
Preliminary Information
ABSOLUTE MAXIMUM RATINGS1
Symbol Parameter
Rating
Unit
VI
Inputs
-0.5 to VCC +0.5
V
VO
Outputs
-0.5 to VCC +0.5
V
VCC
Power Supply Voltage
TS
V
4.6
Storage Temperature
o
-45 to +100
C
Table 7: Absolute Maximum Ratings
Note 1: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the
device. These ratings are stress specifications only. Functional operation of product at these conditions
or any conditions beyond those listed in Recommended Conditions of Operation, DC Characteristics, or
AC Characteristics is not implied. Exposure to absolute maximum rating conditions for extended periods
may affect product reliability.
RECOMMENDED CONDITIONS OF OPERATION
Symbol Parameter
VCC
TA
Positive Supply Voltage
Ambient Operating Temperature
Commercial
Industrial
Min
Typ
Max
Unit
3.135
3.3
3.465
V
0
-40
oC
+70
+85
oC
Table 8: Recommended Conditions of Operation
M1040 Datasheet Rev 0.1
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M1040
Integrated
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VCSO BASED CLOCK PLL WITH AUTOSWITCH
Preliminary Information
ELECTRICAL SPECIFICATIONS
DC Characteristics
Unless stated otherwise, VCC = 3.3V +5%,TA = 0 oC to +70 oC (commercial), TA = -40 oC to +85 oC (industrial), FVCSO = FOUT = 150-175MHz,
LVPECL outputs terminated with 50Ω to VCC - 2V
Symbol Parameter
Power Supply VCC
Positive Supply Voltage
ICC
Power Supply Current
All
Differential
Inputs
VP-P
Peak to Peak Input Voltage
VCMR
Common Mode Input
CIN
Input Capacitance
Differential
Inputs with
Pull-down
IIH
Input High Current (Pull-down)
IIL
Input Low Current (Pull-down)
Differential
Inputs
Biased to
VCC/2
All LVCMOS
/ LVTTL
Inputs
IIH
Input High Current (Biased)
IIL
Input Low Current (Biased)
Rbias
Biased to Vcc/2
VIH
Input High Voltage
VIL
Input Low Voltage
CIN
Input Capacitance
LVCMOS /
LVTTL
Inputs with
Pull-down
LVCMOS /
LVTTL
Inputs with
Pull-UP
Differential
Outputs
IIH
Input High Current (Pull-down)
IIL
Input Low Current (Pull-down)
LVCMOS
Outputs
DIF_REF0, nDIF_REF0,
DIF_REF1, nDIF_REF1
DIF_REF0, DIF_REF1
Min
Typ
Max
Unit Conditions
3.135
3.3
3.465
V
175
225
V
0.5
Vcc - .85 V
4
pF
150
µA
µA
-5
Rpulldown Internal Pull-down Resistance
150
µA
µA
-150
VIN =
0 to 3.456V
See Figure 4
2
AUTO, REF_SEL,, P_SEL,
MR_SEL2, MR_SEL1,
MR_SEL0, INIT, NBW
IIH
Input High Current (Pull-UP)
IIL
Input Low Current (Pull-UP)
Rpullup
Internal Pull-UP Resistance
VOH
Output High Voltage
VOL
Output Low Voltage
VP-P
Peak to Peak Output Voltage 1
VOH
Output High Voltage
VOL
Output Low Voltage
Vcc + 0.3 V
-0.3
AUTO, REF_SEL, P_SEL
0.8
V
4
pF
150
µA
µA
-5
Rpulldown Internal Pull-down Resistance
M1040 Datasheet Rev 0.1
µA
-150
FOUT1, nFOUT1
FOUT0, nFOUT0
Vcc - 1.4
Vcc - 1.0 V
Vcc - 2.0
Vcc - 1.7 V
0.4
0.85
V
2.4
VCC
V
IOH= 1mA
GND
0.4
V
IOL= 1mA
LOL, REF_ACK
Communications Modules
VCC = 3.456V
VIN = 0 V
kΩ
50
Table 9: DC Characteristics
10 of 12
●
µA
5
MR_SEL2, MR_SEL1,
MR_SEL0, INIT, NBW
VCC = VIN =
3.456V
kΩ
50
Note 1: Single-ended measurement. See Figure 6, Input and Output Rise and Fall Time, on pg. 11.
Integrated Circuit Systems, Inc.
VCC = VIN =
3.456V
kΩ
50
nDIF_REF0, nDIF_REF1
mA
0.15
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M1040
Integrated
Circuit
Systems, Inc.
VCSO BASED CLOCK PLL WITH AUTOSWITCH
Preliminary Information
ELECTRICAL SPECIFICATIONS (CONTINUED)
AC Characteristics
Unless stated otherwise, VCC = 3.3V +5%,TA = 0 oC to +70 oC (commercial), TA = -40 oC to +85 oC (industrial), FVCSO = FOUT = 150-175MHz,
LVPECL outputs terminated with 50Ω to VCC - 2V
Symbol Parameter
PLL Loop
Constants 1
Min
Max
Unit Conditions
15
700
MHz
175
MHz
FIN
Input Frequency
DIF_REF0, nDIF_REF0,
DIF_REF1, nDIF_REF1
FOUT
Output Frequency
FOUT0, nFOUT0, FOUT1, nFOUT1
62.5
APR
Absolute Pull-Range
of VCSO
Commercial
±120
±50
KVCO
VCO Gain
RIN
Internal Loop Resistor
Industrial
Wide Bandwidth
Narrow Bandwidth
BWVCSO VCSO Bandwidth
Phase Noise
and Jitter
1kHz Offset
Φn
Single Side Band
Phase Noise
@155.52MHz
J(t)
Jitter (rms)
@155.52MHz
odc
Output Duty Cycle 2
tR
tF
10kHz Offset
100kHz Offset
12kHz to 20MHz
Output Rise Time
2
for
FOUT0, nFOUT0, FOUT1, nFOUT1
Output Fall Time 2 for
FOUT0, nFOUT0, FOUT1, nFOUT1
Typ
±200
±150
200
ppm
ppm
kHz/V
100
kΩ
2100
kΩ
700
kHz
-72
-94
-123
dBc/Hz Fin=19.44_MHz
dBc/Hz Tot. PLL ratio =
8. See pg. 3
dBc/Hz
0.4
0.6
ps
45
50
55
%
350
450
550
ps
20% to 80%
350
450
550
ps
20% to 80%
Table 10: AC Characteristics
Note 1: Parameters needed for PLL Simulator software; see Table 6, Example External Loop Filter Component Values, on pg. 8.
Note 2: See Parameter Measurement Information on pg. 11.
PARAMETER MEASUREMENT INFORMATION
Input and Output Rise and Fall Time
80%
Output Duty Cycle
nFOUT
80%
V P -P
Clock Inputs 20%
and Outputs
20%
tF
tR
Figure 6: Input and Output Rise and Fall Time
FOUT
odc =
Differential Input Level
tPW
(Output Pulse Width)
tPW
tPERIOD
tPERIOD
VCC - 0.85
Figure 8: Output Duty Cycle
nDIF_CLK
VP-P
VCMR
Cross Points
DIF_CLK
+ 0.5
Figure 7: Differential Input Level
M1040 Datasheet Rev 0.1
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M1040
Preliminary Information
VCSO BASED CLOCK PLL WITH AUTOSWITCH
DEVICE PACKAGE - 9 x 9mm CERAMIC LEADLESS CHIP CARRIER
Mechanical Dimensions:
Figure 9: Device Package - 9 x 9mm Ceramic Leadless Chip Carrier
ORDERING INFORMATION
Part Numbering Scheme
Part Number:
Standard VCSO Output Frequencies (MHz)*
M1040- 1z - xxx.xxxx
Output type
1 = LVPECL
(For CML or LVDS clock output, consult factory)
Hitless Switching / Phase Build-out Options
1 = none
2 = Hitless Switching
3 = Hitless Switching with Phase Build-out
Temperature
“ - ” = 0 to +70 oC (commercial)
I = - 40 to +85 oC (industrial)
PLL Frequency (MHz)
See Table 11, right. Consult ICS for other frequencies.
155.5200
167.3280
156.2500
167.3316
156.8324
167.7097
161.1328
168.0400
166.6286
172.6423
167.2820
173.3708
Table 11: Standard VCSO Output Frequencies
*
Figure 10: Part Numbering Scheme
Fout can equal Fvcso divided by: 1 or 2
Consult ICS for the availability of other VCSO frequencies.
Example Part Numbers
VCSO Frequency (MHz) Temperature
commercial
industrial
commercial
industrial
155.52
156.25
Order Part Number (Examples)
M1040- 11 - 155.5200
M1040- 11I 155.5200
M1040 - 11 - 156.2500
M1040- 11I 156.2500
Table 12: Example Part Numbers
While the information presented herein has been checked for both accuracy and reliability, Integrated Circuit Systems (ICS)
assumes no responsibility for either its use or for the infringement of any patents or other rights of third parties, which would
result from its use. No other circuits, patents, or licenses are implied. This product is intended for use in normal commercial
applications. Any other applications such as those requiring extended temperature range, high reliability, or other extraordinary
environmental requirements are not recommended without additional processing by ICS. ICS reserves the right to change any
circuitry or specifications without notice. ICS does not authorize or warrant any ICS product for use in life support devices or
critical medical instruments.
M1040 Datasheet Rev 0.1
Integrated Circuit Systems, Inc.
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