FREESCALE MPC9600FA

MOTOROLA
Freescale Semiconductor, Inc.
Order Number: MPC9600/D
Rev. 2, 11/2001
SEMICONDUCTOR TECHNICAL DATA
Low Voltage 2.5 V and 3.3 V
CMOS PLL Clock Driver
The MPC9600 is a low voltage 2.5 V or 3.3 V compatible, 1:21 PLL
based clock driver and fanout buffer. With output frequencies up to 200
MHz and output skews of 150 ps, the device meets the needs of the most
demanding clock tree applications.
Features:
• Multiplication of input frequency by 2, 3, 4 and 6
• Distribution of output frequency to 21 outputs organized in three output
banks: QA0-QA6, QB0-QB6, QC0-QC6, each fully selectable
Freescale Semiconductor, Inc...
• Fully integrated PLL
• Selectable output frequency range is 50 to 100 MHz and 100 to 200 MHz
MPC9600
3.3 V OR 2.5 V
LOW VOLTAGE CMOS
PLL CLOCK DRIVER
• Selectable input frequency range is 16.67 to 33 MHz and 25 to 50 MHz
• LVCMOS outputs
• Outputs disable to high impedance (except QFB)
• LVCMOS or LVPECL reference clock options
• 48 lead QFP packaging
• ±50 ps cycle-to-cycle jitter
• 150 ps maximum output-to-output skew
• 200 ps maximum static phase offset window
FA SUFFIX
The MPC9600 is a fully LVCMOS 2.5 V or 3.3 V compatible PLL clock
48–LEAD LQFP PACKAGE
driver. The MPC9600 has the capability to generate clock signals of 50 to
CASE 932–03
200 MHz from clock sources of 16.67 to 50 MHz. The internal PLL is
optimized for this frequency range and does not require external loop filter
components. QFB provides an output for the external feedback path to
the feedback input FB_IN. The QFB divider ratio is configurable and
determines the PLL frequency multiplication factor when QFB is directly
connected to FB_IN. The MPC9600 is optimized for minimizing the
propagation delay between the clock input and FB_IN.
Three output banks of 7 outputs each bank can be individually configured to divide the VCO frequency by 2 or by 4. Combining
the feedback and output divider ratios, the MPC9600 is capable to multiply the input frequency by 2, 3, 4 and 6.
The reference clock is selectable either LVPECL or LVCMOS. The LVPECL reference clock feature allows the designer to use
LVPECL fanout buffers for the inner branches of the clock distribution tree. All control inputs accept LVCMOS compatible levels.
The outputs provide low impedance LVCMOS outputs capable of driving parallel terminated 50 Ω transmission to VTT=VCC/2.
For series terminated lines the MPC9600 can drive two lines per output giving the device an effective total fanout of 1:42. With
guaranteed maximum output-to-output skew of 150 ps, the MPC9600 PLL clock driver meets the synchronization requirements
of the most demanding systems.
The VCCA analog power pin doubles as a PLL bypass select line for test purpose. When the VCCA is driven to GND the
reference clock will bypass the PLL.
The device is packaged in a 48-lead LQFP package to provide optimum combination of board density and performance.
 Motorola, Inc. 2001
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VCCA
CCLK
PCLK
(pulldown)
FB_IN
FSELA
Ref
/2
PLL
1
1
PCLK
REF_SEL
0
0
(pulldn)
VCC
7
/4
Bank A
QA0
D
QA1
Q
1
FB
Vcc/2
(pullup)
0
/8
200 - 400 MHz
QA2
/12
QA3
(pulldown)
QA4
(pullup)
Freescale Semiconductor, Inc...
QA5
0
D
7
(pullup)
0
Bank C
D
QC0–6
Q
7
1
FSELC
QB0–6
Q
1
FSELB
QA6
Bank B
(pullup)
0
Feedback
D
Q
QFB
1
FSEL_FB
OE
(pullup)
(pulldown)
8
GND
Figure 1. MPC9600 Logic Diagram
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PIN CONFIGURATION
I/O
Type
Description
QAn
Output
LVCMOS
Bank A outputs
QBn
Output
LVCMOS
Bank B outputs
QCn
Output
LVCMOS
Bank C outputs
QFB
Output
LVCMOS
Differential feedback output
REF_SEL
Input
LVCMOS
Reference clock input select
FSELA
Input
LVCMOS
Selection of bank A output frequency
FSELB
Input
LVCMOS
Selection of bank B output frequency
FSELC
Input
LVCMOS
Selection of bank C output frequency
FSEL_FB
Input
LVCMOS
Selection of feedback frequency
OE
Input
LVCMOS
Output enable
VCCA
Power supply
Analog power supply and PLL bypass. An external VCC filter is recommended for VCCA
VCC
Power supply
Core power supply
GND
Ground
Ground
VCC
PLL feedback clock input
QB6
LVCMOS
QB5
Input
QB4
FB_IN
GND
Reference clock input
QB3
LVCMOS
QB2
Input
VCC
CCLK
QB1
Differential reference clock frequency input
QB0
PECL
QFB
Input
GND
PCLK, PCLK
36
35
34
33
32
31
30
29
28
27
26
25
VCC
37
24
GND
QA6
38
23
QC0
QA5
39
22
QC1
QA4
40
21
QC2
GND
41
20
VCC
QA3
42
19
QC3
MPC9600
QC5
QA0
46
15
QC6
FB_IN
47
14
OE
GND
48
13
VCC
1
2
3
4
5
6
7
8
9
10
11
12
GND
16
FSELC
45
FSELB
QA1
FSELA
GND
VCCA
17
FSEL_FB
44
REF_SEL
VCC
VCC
QC4
PCLK
18
PCLK
43
CCLK
QA2
GND
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Pin
Figure 2. 48 Lead Package Pinout (Top View)
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FUNCTION TABLE (CONTROLS)
Control Pin
0
1
REF_SEL
CCLK
PCLK
VCCA
PLL Bypass1
PLL Power
OE
Outputs Enabled
Outputs Disabled (except QFB)
FSELA
Output Bank A at VCO/2
Output Bank A at VCO/4
FSELB
Output Bank B at VCO/2
Output Bank B at VCO/4
FSELC
Output Bank C at VCO/2
Output Bank C at VCO/4
FSEL_FB
Feedback Output at VCO/8
Feedback Output at VCO/12
1..VCCA = GND, PLL off and bypassed for static test and diagnosis
Table 1: ABSOLUTE MAXIMUM RATINGS*
Symbol
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Min
Max
Unit
VCC
Supply Voltage
Parameter
–0.3
4.6
V
VIN
DC Input Voltage
–0.3
VCC + 0.3
V
VOUT
DC Output Voltage
–0.3
VCC + 0.3
V
IIN
DC Input Current
±20
mA
IOUT
DC Output Current
±50
mA
TStor
Storage Temperature Range
–40
125
°C
* Absolute maximum continuous ratings are those values beyond which damage to the device may occur. Exposure to these conditions or
conditions beyond those indicated may adversely affect device reliability. Functional operation under absolute–maximum–rated conditions is
not implied.
Table 2: GENERAL SPECIFICATIONS
Symbol
Characteristics
VTT
Output Termination Voltage
Min
Typ
VCC
Max
B2
Unit
MM
ESD Protection (Machine Model)
400
V
HBM
ESD Protection (Human Body Model)
4000
V
CDM
ESD Protection (Charged Device Model)
1500
V
Latch–Up Immunity
200
mA
LU
Condition
V
CPD
Power Dissipation Capacitance
10
pF
Per output
CIN
Input Capacitance
4.0
pF
Inputs
Table 3: DC CHARACTERISTICS (VCC = 3.3 V ±5%, TA = –40° to +85°C)
Symbol
Characteristics
Min
VIH
Input High Voltage
VIL
Input Low Voltage
VPP
Peak-to-peak Input Voltage (DC)
PCLK, PCLK
250
VCMRa
Common Mode Range (DC)
PCLK, PCLK
1.0
VOH
Output High Voltage
VOL
Output Low Voltage
ZOUT
Output Impedance
IIN
Input Leakage Current
ICCA
Maximum PLL Supply Current
Typ
2.0
Max
Unit
VCC + 0.3
V
LVCMOS
0.8
V
LVCMOS
mV
LVPECL
V
LVPECL
V
IOH=-24 mAb
V
V
IOL= 24mA
IOL= 12mA
VCC-0.6
2.4
0.55
0.30
W
14 – 17
2.0
Condition
±150
µA
VIN = VCC or GND
5.0
mA
VCCA Pin
ICCQ
Maximum Quiescent Supply Current
1.0
mA
All VCC Pins
a. VCMR (DC) is the crosspoint of the differential input signal. Functional operation is obtained when the crosspoint is within the VCMR range
and the input swing lies within the VPP (DC) specification.
b. The MPC9600 is capable of driving 50Ω transmission lines on the incident edge. Each output drives one 50Ω parallel terminated
transmission line to a termination voltage of VTT. Alternatively, the device drives up to two 50Ω series terminated transmission lines.
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Table 4: DC CHARACTERISTICS (VCC = 2.5 V ±5%, TA = –40° to +85°C)
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Symbol
Characteristics
Min
VIH
Input High Voltage
VIL
Input Low Voltage
VPP
Peak-to-peak input voltage (DC)
PCLK, PCLK
250
VCMRa
Common Mode Range (DC)
PCLK, PCLK
1.0
VOH
Output High Voltage
VOL
Output Low Voltage
ZOUT
Output Impedance
IIN
Input Leakage Current
ICCA
Maximum PLL Supply Current
Typ
1.7
Max
Unit
VCC + 0.3
V
LVCMOS
0.7
V
LVCMOS
mV
LVPECL
V
LVPECL
V
IOH=-15 mAb
V
IOL= 15 mA
VCC-0.6
1.8
0.6
W
17 – 20
3.0
Condition
±150
µA
VIN = VCC or GND
5.0
mA
VCCA Pin
ICCQ
Maximum Quiescent Supply Current
1.0
mA
All VCC Pins
a. VCMR (DC) is the crosspoint of the differential input signal. Functional operation is obtained when the crosspoint is within the VCMR range
and the input swing lies within the VPP (DC) specification.
b. The MPC9600 is capable of driving 50 Ω transmission lines on the incident edge. Each output drives one 50 Ω parallel terminated
transmission line to a termination voltage of VTT. Alternatively, the device drives up to two 50 Ω series terminated transmission lines per
output.
Table 5: AC CHARACTERISTICS (VCC = 3.3 V ±5% or VCC = 2.5 V ±5%, TA = –40° to +85°C)a
Characteristics
Symbol
fref
Input Frequency
Min
B8 feedback (FSEL_FB=0)
B12 feedback (FSEL_FB=1)
Static test mode (VCCA = GND)
fVCO
VCO Frequency
fMAX
Maximum Output Frequency
B2 outputs (FSELx=0)
B4 outputs (FSELx=1)
Typ
Max
Unit
Condition
25
16.67
50
33
MHz
MHz
PLL locked
PLL locked
0
500
MHz
VCCA = GND
200
400
MHz
100
50
200
100
MHz
MHz
25
75
%
PLL locked
PLL locked
frefDC
Reference Input Duty Cycle
VPP
Peak-to-peak Input Voltage
PCLK, PCLK
500
1000
mV
LVPECL
VCMRb
Common Mode Range
PCLK, PCLK (VCC = 3.3 V ±5%)
PCLK, PCLK (VCC = 2.5 V ±5%)
1.2
1.2
VCC-0.8
VCC-0.6
V
V
LVPECL
LVPECL
1.0
ns
see Figure 12
+40
+130
+140
+230
ps
ps
PLL locked
PLL locked
all outputs, single frequency
all outputs, multiple frequency
70
70
150
150
ps
ps
Measured at
coincident
rising edge
within QAx output bank
within QBx outputs
within QCx outputs
30
40
30
75
125
75
ps
ps
ps
50
55
%
1.0
ns
tr, tf
CCLK Input Rise/Fall Time
t(∅)
Propagation Delay (static phase offset)
CCLK to FB_IN
PECL_CLK to FB_IN
tsk(o)
–60
+30
Output-to-output Skew
DC
Output Duty Cycle
45
tr, tf
Output Rise/Fall Time
0.1
tPLZ, HZ
Output Disable Time
10
ns
tPZL, ZH
Output Enable Time
10
ns
BW
PLL Closed Loop Bandwidth
8 feedback (FSEL_FB=0)
12 feedback (FSEL_FB=1)
TIMING SOLUTIONS
B
B
1.0 – 10
0.6 – 4.0
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MHz
MHz
see Figure 12
–3 dB point of
PLL transfer
characteristic
MOTOROLA
Freescale Semiconductor, Inc.
Table 5: AC CHARACTERISTICS (VCC = 3.3 V ±5% or VCC = 2.5 V ±5%, TA = –40° to +85°C)a
Symbol
tJIT(CC)
tJIT(PER)
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tJIT(∅)
Characteristics
Cycle-to-cycle Jitterc
Typ
Max
Unit
Condition
All outputs in
All outputs in
B2 configuration
B4 configuration
40
40
130
180
ps
ps
See application
section for
other
configurations
All outputs in
All outputs in
B2 configuration
B4 configuration
25
20
70
100
ps
ps
See application
section for
other
configurations
17d
15c
ps
ps
RMS value at
fVCO=400MHz
Period Jitterc
I/O Phase Jitter (1 s)
Min
VCC = 3.3V
VCC = 2.5V
tLOCK
Maximum PLL Lock Time
5.0
ms
a. AC characteristics are applicable over the entire ambient temperature and supply voltage range and are production tested. AC
characteristics apply for parallel output termination of 50 Ω to VTT.
b. VCMR (AC) is the crosspoint of the differential input signal. Normal AC operation is obtained when the crosspoint is within the VCMR range
and the input swing lies within the VPP (AC) specification. Violation of VCMR or VPP impacts static phase offset t(∅).
c. Cycle–to–cycle and period jitter depends on output divider configuration.
d. See applications section for max I/O phase jitter versus frequency.
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configurations, the table describes the outputs using the
input clock frequency CLK as a reference.
Programming the MPC9600
The feedback divider division settings establish the output
relationship,
in addition, it must be ensured that the VCO will
The MPC9600 clock driver outputs can be configured into
be stable given the frequency of the outputs desired. The
several divider modes. Additionally the external feedback of
feedback frequency should be used to situate the VCO into a
the device allows for flexibility in establishing various input to
frequency range in which the PLL will be stable. The design
output frequency relationships. The selectable feedback
of the PLL supports output frequencies from 50 MHz to 200
divider of the three output groups allows the user to configure
MHz while the VCO frequency range is specified from 200
the device for 1:2, 1:3, 1:4 and 1:6 input:output frequency
MHz to 400 MHz and should not be exceeded for stable
ratios. The use of even dividers ensure that the output duty
operation.
cycle is always 50%. Table 6 illustrates the various output
Table 6: Output Frequency Relationshipa for QFB connected to FB_IN
APPLICATIONS INFORMATION
Freescale Semiconductor, Inc...
Configuration Inputs
FSEL_FB
FSELA
FSELB
FSELC
0
0
0
0
0
0
0
0
0
0
Input
Frequency
Range CLK
[MHz]
Output Frequency Ratio and Range
Ratio, QAx [MHz]
Ratio, QBx [MHz]
0
4SCLK
(100–200)
4SCLK
(100–200)
4SCLK
(100–200)
1
4SCLK
(100–200)
4SCLK
(100–200)
2SCLK
(50.0–100)
1
0
4SCLK
(100–200)
2SCLK
(50.0–100)
4SCLK
(100–200)
0
1
1
4SCLK
(100–200)
2SCLK
(50.0–100)
2SCLK
(50.0–100)
1
0
0
2SCLK (50.0–100)
4SCLK
(100–200)
4SCLK
(100–200)
0
1
0
1
2SCLK
(50.0–100)
4SCLK
(100–200)
2SCLK
(50.0–100)
0
1
1
0
2SCLK
(50.0–100)
2SCLK
(50.0–100)
4SCLK
(100–200)
0
1
1
1
2SCLK
(50.0–100)
2SCLK
(50.0–100)
2SCLK
(50.0–100)
1
0
0
0
6SCLK
(100–200)
6SCLK
(100–200)
6SCLK
(100–200)
1
0
0
1
6SCLK
(100–200)
6SCLK
(100–200)
3SCLK
(50.0–100)
1
0
1
0
6SCLK
(100–200)
3SCLK
(50.0–100)
6SCLK
(100–200)
1
0
1
1
6SCLK
(100–200)
3SCLK
(50.0–100)
3SCLK
(50.0–100)
1
1
0
0
3SCLK
(50.0–100)
6SCLK
(100–200)
6SCLK
(100–200)
1
1
0
1
3SCLK
(50.0–100)
6SCLK
(100–200)
3SCLK
(50.0–100)
1
1
1
0
3SCLK
(50.0–100)
3SCLK
(50.0–100)
6SCLK
(100–200)
1
1
1
1
3SCLK
(50.0–100)
3SCLK
(50.0–100)
3SCLK
(50.0–100)
25.0–50.0
16.67–33.33
Ratio, QCx [MHz]
a. Output frequency relationship with respect to input reference frequency CLK. The VCO frequency range is always 200–400.
Typical and Maximum Period Jitter Specification
QA0 to QA6
Device Configuration
B B
All output banks in 2 or 4 divider configurationa
2 (FSELA=0 and FESLB=0 and FSELC=0)
4 (FSELA=1 and FESLB=1 and FSELC=1)
Mixed 2/ 4 divider configurationsb
for output banks in 2 divider configurations
for output banks in 4 divider configurations
B
B
B B
B
B
QB0 to QB6
QC0 to QC6
Typ
Max
Typ
Max
Typ
Max
25
20
50
70
50
50
70
100
25
20
50
70
80
25
130
70
100
60
150
100
80
25
130
70
a. In this configuration, all MPC9600 outputs generate the same clock frequency. See Figure 1 for an example configuration.
b. Multiple frequency generation. Jitter data are specified for each output divider sepeerately. See Figure 2 for an example.
Typical and Maximum Cycle–to–cycle Jitter Specification
QA0 to QA6
Device Configuration
B B
All output banks in 2 or 4 divider configurationa
2 (FSELA=0 and FESLB=0 and FSELC=0)
4 (FSELA=1 and FESLB=1 and FSELC=1)
Mixed 2/ 4 divider configurationsb
for output banks in 2 divider configurations
for output banks in 4 divider configurations
B
B
B B
B
B
QB0 to QB6
QC0 to QC6
Typ
Max
Typ
Max
Typ
Max
40
40
90
110
80
120
130
180
40
40
90
110
150
30
250
110
200
120
280
180
150
30
250
110
a. In this configuration, all MPC9600 outputs generate the same clock frequency.
b. Multiple frequency generation. Jitter data are specified for each output divider sepeerately.
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Figure 3. Configuration for 125 MHz clocks
fref = 20.833 MHz
CCLK
QA0–6
Figure 4. Configuration for 133.3/66.67 MHz clocks
fref = 33.33 MHz
125 MHz
CCLK
QA0–6
7
QB0–6
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125 MHz
QB0–6
7
FB_IN
1
FSEL_FB
0
0
0
FSELA
FSELB
FSELC
133.3 MHz
7
QC0–6
125 MHz
7
QFB
66.67 MHz
7
FB_IN
0
FSEL_FB
0
1
1
FSELA
FSELB
FSELC
66.67 MHz
QC0–6
7
QFB
MPC9600
MPC9600
20.833 MHz (Feedback)
33.33 MHz (Feedback)
Frequency range
Min
Max
Frequency range
Min
Max
Input
16.67 MHz
33.33 MHz
Input
25 MHz
50 MHz
QA outputs
100 MHz
200 MHz
QA outputs
100 MHz
200 MHz
QB outputs
100 MHz
200 MHz
QB outputs
100 MHz
200 MHz
QC outputs
100 MHz
200 MHz
QC outputs
100 MHz
200 MHz
Power Supply Filtering
The MPC9600 is a mixed analog/digital product. Its analog
circuitry is naturally susceptible to random noise, especially if
this noise is seen on the power supply pins. Random noise
on the VCCA (PLL) power supply impacts the device
characteristics, for instance I/O jitter. The MPC9600 provides
separate power supplies for the output buffers (VCC) and the
phase-locked loop (VCCA) of the device.The purpose of this
design technique is to isolate the high switching noise digital
outputs from the relatively sensitive internal analog
phase-locked loop. In a digital system environment where it
is more difficult to minimize noise on the power supplies a
second level of isolation may be required. The simple but
effective form of isolation is a power supply filter on the VCCA
pin for the MPC9600. Figure 5. illustrates a typical power
supply filter scheme. The MPC9600 frequency and phase
stability is most susceptible to noise with spectral content in
the 100kHz to 20MHz range. Therefore the filter should be
designed to target this range. The key parameter that needs
to be met in the final filter design is the DC voltage drop
across the series filter resistor RF. From the data sheet the
ICCA current (the current sourced through the VCCA pin) is
typically 3 mA (5 mA maximum), assuming that a minimum of
2.325 V (VCC=3.3 V or VCC=2.5 V) must be maintained on
the VCCA pin. The resistor RF shown in Figure 5. “VCCA
Power Supply Filter” must have a resistance of 9-10
(VCC=2.5 V) to meet the voltage drop criteria.
The minimum values for RF and the filter capacitor CF are
defined by the required filter characteristics: the RC filter
should provide an attenuation greater than 40 dB for noise
whose spectral content is above 100 kHz. In the example RC
filter shown in Figure 5. “VCCA Power Supply Filter”, the filter
cut-off frequency is around 3-5 kHz and the noise attenuation
at 100 kHz is better than 42 dB.
W
MOTOROLA
RF = 9–10 Ω for VCC = 2.5 V or VCC = 3.3 V
CF = 22 µF for VCC = 2.5 V or VCC = 3.3 V
RF
VCCA
VCC
CF
10 nF
MPC9600
VCC
33...100 nF
Figure 5. VCCA Power Supply Filter
As the noise frequency crosses the series resonant point
of an individual capacitor its overall impedance begins to look
inductive and thus increases with increasing frequency. The
parallel capacitor combination shown ensures that a low
impedance path to ground exists for frequencies well above
the bandwidth of the PLL. Although the MPC9600 has
several design features to minimize the susceptibility to
power supply noise (isolated power and grounds and fully
differential PLL) there still may be applications in which
overall performance is being degraded due to system power
supply noise. The power supply filter schemes discussed in
this section should be adequate to eliminate power supply
noise related problems in most designs.
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Using the MPC9600 in zero–delay applications
Nested clock trees are typical applications for the
MPC9600. For these applications the MPC9600 offers a
differential LVPECL clock input pair as a PLL reference. This
allows for the use of differential LVPECL primary clock
distribution devices such as the Motorola MC100ES6111 or
MC100ES6226, taking advantage of its superior low-skew
performance. Clock trees using LVPECL for clock distribution
and the MPC9600 as LVCMOS PLL fanout buffer with zero
insertion delay will show significantly lower clock skew than
clock distributions developed from CMOS fanout buffers.
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The external feedback option of the MPC9600 PLL allows
for its use as a zero delay buffer. The PLL aligns the feedback
clock output edge with the clock input reference edge and
virtually eliminates the propagation delay through the device.
The remaining insertion delay (skew error) of the
MPC9600 in zero-delay applications is measured between
the reference clock input and any output. This effective delay
consists of the static phase offset (SPO or t(∅)), I/O jitter
(tJIT(∅), phase or long-term jitter), feedback path delay and
the output-to-output skew (tSK(O) relative to the feedback
output.
Calculation of part-to-part skew
The MPC9600 zero delay buffer supports applications
where critical clock signal timing can be maintained across
several devices. If the reference clock inputs (CCLK or
PCLK) of two or more MPC9600 are connected together, the
maximum overall timing uncertainty from the common CCLK
input to any output is:
tSK(PP) = t( ∅) + tSK(O) + tPD, LINE(FB) + tJIT( ∅) CF
This maximum timing uncertainty consist of 4
components: static phase offset, output skew, feedback
board trace delay and I/O (phase) jitter:
TCLKCommon
QFBDevice 1
± 1s
0.68268948
± 2s
0.95449988
± 3s
0.99730007
± 4s
0.99993663
± 5s
0.99999943
± 6s
0.99999999
The feedback trace delay is determined by the board
layout and can be used to fine-tune the effective delay
through each device. In the following example calculation a
I/O jitter confidence factor of 99.7% (± 3s) is assumed,
resulting in a worst case timing uncertainty from input to any
output of -261 ps to 341 ps relative to CCLK (VCC=3.3V and
fVCO = 200 MHz):
tSK(PP) =
[–60ps...140ps] + [–150ps...150ps] +
[(17ps @ –3)...(17ps @ 3)] + tPD, LINE(FB)
tSK(PP) =
[–261ps...341ps] + tPD, LINE(FB)
Above equation uses the maximum I/O jitter number
shown in the AC characteristic table for VCC=3.3V (17 ps
RMS). I/O jitter is frequency dependant with a maximum at
the lowest VCO frequency (200 MHz for the MPC9600).
Applications using a higher VCO frequency exhibit less I/O
jitter than the AC characteristic limit. The I/O jitter
characteristics in Figure 7. can be used to derive a smaller
I/O jitter number at the specific VCO frequency, resulting in
tighter timing limits in zero-delay mode and for part-to-part
skew tSK(PP).
+tSK(O)
QFBDevice2
Figure 7. Max. I/O Jitter versus VCO frequency for
VCC=2.5V and VCC=3.3V
tJIT(∅)
+tSK(O)
tSK(PP)
Figure 6. MPC9600 max. device-to-device skew
Due to the statistical nature of I/O jitter a RMS value (1 s)
is specified. I/O jitter numbers for other confidence factors
(CF) can be derived from Table 8.
TIMING SOLUTIONS
Probability of clock edge within the distribution
tJIT(∅)
+t(∅)
Max. skew
CF
tPD,LINE(FB)
–t(∅)
Any QDevice 1
Any QDevice 2
Table 8: Confidence Facter CF
Driving Transmission Lines
The MPC9600 clock driver was designed to drive high
speed signals in a terminated transmission line environment.
To provide the optimum flexibility to the user the output
drivers were designed to exhibit the lowest impedance
possible. With an output impedance of less than 20 Ω the
drivers can drive either parallel or series terminated
transmission lines. For more information on transmission
lines the reader is referred to Motorola application note
AN1091. In most high performance clock networks
point-to-point distribution of signals is the method of choice.
In a point-to-point scheme either series terminated or parallel
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MOTOROLA
Freescale Semiconductor, Inc.
MPC9600
OUTPUT
BUFFER
IN
14Ω
RS = 36 Ω
ZO = 50 Ω
OutA
= 50 Ω || 50 Ω
= 36 Ω || 36 Ω
= 14 Ω
= 3.0 ( 25 ÷ (18+17+25)
= 1.31 V
At the load end the voltage will double due to the near unity
reflection coefficient, to 2.6 V. It will then increment towards
the quiescent 3.0 V in steps separated by one round trip
delay (in this case 4.0 ns).
Z0
RS
R0
VL
3.0
2.5
VOLTAGE (V)
Freescale Semiconductor, Inc...
terminated transmission lines can be used. The parallel
technique terminates the signal at the end of the line with a
50Ω resistance to VCC÷2.
This technique draws a fairly high level of DC current and
thus only a single terminated line can be driven by each
output of the MPC9600 clock driver. For the series
terminated case however there is no DC current draw, thus
the outputs can drive multiple series terminated lines.
Figure 8. “Single versus Dual Transmission Lines” illustrates
an output driving a single series terminated line versus two
series terminated lines in parallel. When taken to its extreme
the fanout of the MPC9600 clock driver is effectively doubled
due to its capability to drive multiple lines.
OutA
tD = 3.8956
OutB
tD = 3.9386
2.0
In
1.5
1.0
MPC9600
OUTPUT
BUFFER
IN
RS = 36 Ω
0.5
ZO = 50 Ω
OutB0
0
14Ω
RS = 36 Ω
ZO = 50 Ω
2
4
6
OutB1
8
TIME (nS)
10
12
14
Figure 9. Single versus Dual Waveforms
Figure 8. Single versus Dual Transmission Lines
The waveform plots in Figure 9. “Single versus Dual Line
Termination Waveforms” show the simulation results of an
output driving a single line versus two lines. In both cases the
drive capability of the MPC9600 output buffer is more than
sufficient to drive 50 Ω transmission lines on the incident
edge. Note from the delay measurements in the simulations a
delta of only 43 ps exists between the two differently loaded
outputs. This suggests that the dual line driving need not be
used exclusively to maintain the tight output-to-output skew
of the MPC9600. The output waveform in Figure 9. “Single
versus Dual Line Termination Waveforms” shows a step in
the waveform, this step is caused by the impedance
mismatch seen looking into the driver. The parallel
combination of the 36Ω series resistor plus the output
impedance does not match the parallel combination of the
line impedances. The voltage wave launched down the two
lines will equal:
VL = VS ( Z0 ÷ (RS+R0 +Z0))
MOTOROLA
Since this step is well above the threshold region it will not
cause any false clock triggering, however designers may be
uncomfortable with unwanted reflections on the line. To
better match the impedances when driving multiple lines the
situation in Figure 10. “Optimized Dual Line Termination”
should be used. In this case the series terminating resistors
are reduced such that when the parallel combination is added
to the output buffer impedance the line impedance is
perfectly matched.
MPC9600
OUTPUT
BUFFER
RS = 22 Ω
ZO = 50 Ω
RS = 22 Ω
ZO = 50 Ω
14Ω
14 Ω + 22 Ω k 22 Ω = 50 Ω k 50 Ω
25 Ω = 25 Ω
Figure 10. Optimized Dual Line Termination
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TIMING SOLUTIONS
Freescale Semiconductor, Inc.
The Following Figures Illustrate the Measurement Reference for the MPC9600 Clock Driver Circuit
MPC9600 DUT
ZO = 50 Ω
Pulse
Generator
Z = 50
ZO = 50 Ω
W
RT = 50 Ω
RT = 50 Ω
VTT
VTT
Freescale Semiconductor, Inc...
Figure 11. CCLK MPC9600 AC test reference
Differential
Pulse Generator
Z = 50
MPC9600 DUT
ZO = 50 Ω
ZO = 50 Ω
W
RT = 50 Ω
RT = 50 Ω
VTT
VTT
Figure 12. PCLK MPC9600 AC test reference
VCC
VCC 2
PCLK
VCMR
VPP
PCLK
B
CCLK
GND
VCC
VCC 2
B
FB_IN
VCC
VCC 2
B
FB_IN
GND
GND
t(∅)
t(∅)
Figure 13. Propagation delay t(∅), static phase
offset) test reference
Figure 14. Propagation delay t(∅) test reference
VCC
VCC 2
VCC
VCC 2
GND
GND
B
B
tP
VCC
VCC 2
B
T0
GND
DC = tP /T0 x 100%
tSK(O)
The time from the PLL controlled edge to the non controlled
edge, divided by the time between PLL controlled edges,
expressed as a percentage
Figure 15. Output Duty Cycle (DC)
TIMING SOLUTIONS
The pin–to–pin skew is defined as the worst case difference in
propagation delay between any similar delay path within a
single device
Figure 16. Output–to–output Skew tSK(O)
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Freescale Semiconductor, Inc.
TN
TN+1
TJIT(CC) = |TN –TN+1 |
The variation in cycle time of a signal between adjacent cycles, over a
random sample of adjacent cycle pairs
TJIT(P) = |TN –1/f0 |
T0
The deviation in cycle time of a signal with respect to the ideal period over
a random sample of cycles
Figure 17. Cycle–to–cycle Jitter
Figure 18. Period Jitter
CCLK
(PCLK)
VCC=3.3 V
2.4
Freescale Semiconductor, Inc...
FB_IN
0.55
TJIT(∅) = |T0 –T1 mean|
tF
VCC=2.5 V
1.8 V
0.6 V
tR
The deviation in t0 for a controlled edge with respect to a t0 mean in a
random sample of cycles
Figure 19. I/O Jitter
MOTOROLA
Figure 20. Output Transition Time Test Reference
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TIMING SOLUTIONS
Freescale Semiconductor, Inc.
OUTLINE DIMENSIONS
FA SUFFIX
LQFP PACKAGE
CASE 932–03
ISSUE F
4X
0.200 AB T–U Z
DETAIL Y
A
P
A1
48
37
1
36
U
B
V
AE
B1
12
25
13
AE
V1
24
DIM
A
A1
B
B1
C
D
E
F
G
H
J
K
L
M
N
P
R
S
S1
V
V1
W
AA
Z
S1
T, U, Z
S
DETAIL Y
4X
0.200 AC T–U Z
0.080 AC
G
AB
AD
AC
M_
BASE METAL
ÉÉÉ
ÇÇÇ
ÇÇÇ
ÉÉÉ
ÇÇÇ
ÉÉÉ
MILLIMETERS
MIN
MAX
7.000 BSC
3.500 BSC
7.000 BSC
3.500 BSC
1.400
1.600
0.170
0.270
1.350
1.450
0.170
0.230
0.500 BSC
0.050
0.150
0.090
0.200
0.500
0.700
0 _
7_
12 _REF
0.090
0.160
0.250 BSC
0.150
0.250
9.000 BSC
4.500 BSC
9.000 BSC
4.500 BSC
0.200 REF
1.000 REF
TOP & BOTTOM
N
R
J
0.250
Freescale Semiconductor, Inc...
T
C
E
GAUGE PLANE
9
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME
Y14.5M, 1994.
2. CONTROLLING DIMENSION: MILLIMETER.
3.DATUM PLANE AB IS LOCATED AT BOTTOM OF
LEAD AND IS COINCIDENT WITH THE LEAD
WHERE THE LEAD EXITS THE PLASTIC BODY AT
THE BOTTOM OF THE PARTING LINE.
4.DATUMS T, U, AND Z TO BE DETERMINED AT
DATUM PLANE AB.
5.DIMENSIONS S AND V TO BE DETERMINED AT
SEATING PLANE AC.
6.DIMENSIONS A AND B DO NOT INCLUDE MOLD
PROTRUSION. ALLOWABLE PROTRUSION IS
0.250 PER SIDE. DIMENSIONS A AND B DO
INCLUDE MOLD MISMATCH AND ARE
DETERMINED AT DATUM PLANE AB.
7.DIMENSION D DOES NOT INCLUDE DAMBAR
PROTRUSION. DAMBAR PROTRUSION SHALL
NOT CAUSE THE D DIMENSION TO EXCEED
0.350.
8.MINIMUM SOLDER PLATE THICKNESS SHALL BE
0.0076.
9.EXACT SHAPE OF EACH CORNER IS OPTIONAL.
F
D
0.080
M
AC T–U Z
SECTION AE–AE
W
H
L_
K
DETAIL AD
AA
TIMING SOLUTIONS
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Freescale Semiconductor, Inc.
Freescale Semiconductor, Inc...
NOTES
MOTOROLA
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TIMING SOLUTIONS
Freescale Semiconductor, Inc.
Freescale Semiconductor, Inc...
NOTES
TIMING SOLUTIONS
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Freescale Semiconductor, Inc...
Freescale Semiconductor, Inc.
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MPC9600/D
TIMING
SOLUTIONS