MPC93H52FA [NXP]
93H SERIES, PLL BASED CLOCK DRIVER, 11 TRUE OUTPUT(S), 0 INVERTED OUTPUT(S), PQFP32, LQFP-32;型号: | MPC93H52FA |
厂家: | NXP |
描述: | 93H SERIES, PLL BASED CLOCK DRIVER, 11 TRUE OUTPUT(S), 0 INVERTED OUTPUT(S), PQFP32, LQFP-32 驱动 输出元件 逻辑集成电路 |
文件: | 总16页 (文件大小:322K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
MPC93H52
Rev. 5, 1/2005
Freescale Semiconductor
Technical Data
3.3 V 1:11 LVCMOS Zero Delay
Clock Generator
MPC93H52
The MPC93H52 is a 3.3 V compatible, 1:11 PLL based clock generator
targeted for high performance clock tree applications. With output frequencies up
to 240 MHz and output skews lower than 200 ps the device meets the needs of
most demanding clock applications.
LOW VOLTAGE
3.3 V LVCMOS 1:11
CLOCK GENERATOR
Features
•
•
•
•
Configurable 11 outputs LVCMOS PLL clock generator
Fully integrated PLL
Wide range of output clock frequency of 16.67 MHz to 240 MHz
Multiplication of the input reference clock frequency by 3, 2, 1, 3÷2, 2÷3, 1÷3
and 1÷2
•
•
•
•
3.3 V LVCMOS compatible
FA SUFFIX
32-LEAD LQFP PACKAGE
CASE 873A-03
Maximum output skew of 200 ps
Supports zero-delay applications
Designed for high-performance telecom, networking and computing
applications
•
•
•
•
32-lead LQFP package
AC SUFFIX
32-LEAD LQFP PACKAGE
Pb-FREE PACKAGE
CASE 873A-03
32-lead Pb-free Package Available
Ambient Temperature Range — 0°C to +70°C
Pin and function compatible to the MPC952
Functional Description
The MPC93H52 is a fully 3.3 V compatible PLL clock generator and clock driver. The device has the capability to generate
output clock signals of 16.67 to 240 MHz from external clock sources. The internal PLL is optimized for its frequency range and
does not require external lock filter components. One output of the MPC93H52 has to be connected to the PLL feedback input
FB_IN to close the external PLL feedback path. The output divider of this output setting determines the PLL frequency multipli-
cation factor. This multiplication factor, F_RANGE, and the reference clock frequency must be selected to situate the VCO in its
specified lock range. The frequency of the clock outputs can be configured individually for all three output banks by the FSELx
pins supporting systems with different but phase-aligned clock frequencies.
The PLL of the MPC93H52 minimizes the propagation delay and, therefore, supports zero-delay applications. All inputs and
outputs are LVCMOS compatible. The outputs are optimized to drive parallel terminated 50 Ω transmission lines. Alternatively,
each output can drive up to two series terminated transmission lines giving the device an effective fanout of 22.
The device also supports output high-impedance disable and a PLL bypass mode for static system test and diagnosis. The
MPC93H52 is package in a 32-lead LQFP.
This document contains certain information on a new product.
Specifications and information herein are subject to change without notice.
© Freescale Semiconductor, Inc., 2005. All rights reserved.
Freescale Confidential Proprietary, NDA Required / Preliminary
Bank A
CCLK
VCO
QA0
÷2
1
0
1
0
÷6
÷4
÷2
1
0
QA1
QA2
CCLK
FB_IN
Ref
FB
PLL
QA3
QA4
200 – 480 MHz
PLL_EN
Bank B
QB0
1
0
F_RANGE
QB1
QB2
QB3
FSELA
FSELB
Bank C
1
0
QC0
QC1
FSELC
MR/OE
POWER-ON RESET
(all input resistors have a value of 25 kΩ)
Figure 1. MPC93H52 Logic Diagram
24
23 22 21
20 19 18
17
25
26
27
28
29
30
31
32
16
15
14
13
12
11
10
9
V
V
CC
CC
QA2
QA1
GND
QA0
QB2
QB3
GND
GND
QC0
QC1
MPC93H52
V
CC
V
CCA
V
PLL_EN
CC
1
2
3
4
5
6
7
8
It is recommended to use an external RC filter for the analog power supply pin V . Please see for details.
CCA
Figure 2. MPC93H52 32-Lead Package Pinout (Top View)
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
2
Table 1. Pin Configuration
Pin
I/O
Type
LVCMOS
Function
CCLK
Input
Input
Input
Input
Input
Input
Input
Input
PLL reference clock signal
FB_IN
LVCMOS
LVCMOS
LVCMOS
LVCMOS
LVCMOS
LVCMOS
LVCMOS
LVCMOS
Ground
PLL feedback signal input, connect to an output
PLL frequency range select
F_RANGE
FSELA
Frequency divider select for bank A outputs
Frequency divider select for bank B outputs
Frequency divider select for bank C outputs
PLL enable/disable
FSELB
FSELC
PLL_EN
MR/OE
Output enable/disable (high-impedance tristate) and device reset
Clock outputs
QA0–4, QB0–3, QC0–1
GND
Output
Supply
Supply
Negative power supply
V
V
PLL positive power supply (analog power supply). It is recommended to
CCA
CC
use an external RC filter for the analog power supply pin V
see applications section for details.
. Please
CCA
V
Supply
V
Positive power supply for I/O and core
CC
CC
Table 2. Function Table
Control
Default
0
1
F_RANGE, FSELA, FSELB, and FSELC control the operating PLL frequency range and input/output frequency ratios.
See Table 7 and Table 8 for supported frequency ranges and output to input frequency ratios.
F_RANGE
FSELA
0
0
0
0
0
VCO ÷ 1 (High input frequency range)
Output divider ÷ 4
VCO ÷ 2 (Low input frequency range)
Output divider ÷ 6
FSELB
Output divider ÷ 4
Output divider ÷ 2
FSELC
MR/OE
Output divider ÷ 2
Output divider ÷ 4
Outputs enabled (active)
Outputs disabled (high-impedance state) and
reset of the device. During reset, the PLL
feedback loop is open and the VCO is operating
at its lowest frequency. The MPC93H52 requires
reset after any loss of PLL lock. Loss of PLL lock
may occur when the external feedback path is
interrupted. The length of the reset pulse should
be greater than two reference clock cycles
(CCLK). The device is reset by the internal power-
on reset (POR) circuitry during power-up.
PLL_EN
0
Normal operation mode with PLL enabled.
Test mode with PLL disabled. CCLK is
substituted for the internal VCO output.
MPC93H52 is fully static and no minimum
frequency limit applies. All PLL related AC
characteristics are not applicable.
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
3
Table 3. General Specifications
Symbol
Characteristics
Min
Typ
÷ 2
Max
Unit
V
Condition
V
Output Termination Voltage
ESD (Machine Model)
ESD (Human Body Model)
Latch-Up Immunity
V
TT
CC
MM
HBM
LU
200
2000
200
V
V
mA
pF
pF
C
Power Dissipation Capacitance
Input Capacitance
10
4.0
Per output
Inputs
PD
C
IN
Table 4. Absolute Maximum Ratings(1)
Symbol
Characteristics
Min
Max
3.9
Unit
V
Condition
V
Supply Voltage
–0.3
–0.3
–0.3
CC
V
DC Input Voltage
DC Output Voltage
DC Input Current
DC Output Current
V
V
+0.3
V
IN
CC
V
+0.3
V
OUT
CC
I
±20
mA
mA
°C
IN
I
±50
OUT
T
Storage Temperature
–65
125
S
1. Absolute maximum continuous ratings are those maximum 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 at absolute-maximum-rated
conditions is not implied.
Table 5. DC Characteristics (VCC = 3.3 V ± 5%, TA = 0° to 70°C)
Symbol
Characteristics
Min
Typ
Max
V + 0.3
CC
Unit
V
Condition
LVCMOS
LVCMOS
V
Input High Voltage
Input Low Voltage
2.0
IH
V
0.8
V
IL
(1)
V
Output High Voltage
Output Low Voltage
2.4
V
I
= –24 mA
OH
OH
V
0.55
0.30
V
V
I
I
= 24 mA
= 12 mA
OL
OL
OL
Z
Output Impedance
7 – 10
Ω
OUT
(2)
I
Input Current
±200
12
µA
mA
mA
V
V
= V or V = GND
CC IN
IN
IN
I
Maximum PLL Supply Current
8
Pin
CCA
CCA
(3)
CCQ
I
Maximum Quiescent Supply Current
10
16
All V Pins
CC
1. The MPC93H52 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 V . Alternatively, the device drives up to two 50 Ω series terminated transmission lines.
TT
2. Inputs have pull-down resistors affecting the input current.
3. I
is the DC current consumption of the device with all outputs open in high impedance state and the inputs in its default state or open.
CCQ
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
4
Table 6. AC Characteristics (VCC = 3.3 V ± 5%, TA = 0° to 70°C)(1)
Symbol
Characteristics
Min
Typ
Max
Unit
Condition
f
Input reference frequency
in PLL mode
÷4 feedback
÷6 feedback
÷8 feedback
÷12 feedback
50.0
33.3
25.0
120.0
80.0
60.0
40.0
MHz
MHz
MHz
MHz
ref
(2) (3)
16.67
(4)
Input reference frequency in PLL bypass mode
50.0
200
250.0
480
MHz
MHz
(5)
f
f
VCO lock frequency range
VCO
MAX
(6)
Output Frequency
÷2 output
100
50
33.3
25
240
120
80
60
40
MHz
MHz
MHz
MHz
MHz
÷4 output
÷6 output
÷8 output
÷12 output
16.67
t
Minimum Reference Input Pulse Width
2.0
ns
ns
PWMIN
(7)
t , t
CCLK Input Rise/Fall Time
1.0
0.8 to 2.0 V
PLL locked
r
f
t
Propagation Delay CCLK to FB_IN
(static phase offset)
(f = 50 MHz)
–200
+200
ps
ps
(∅)
ref
(8)
t
Output-to-output Skew
all outputs, any frequency
within QA output bank
within QB output bank
within QC output bank
300
200
200
100
ps
ps
ps
ps
sk(O)
DC
Output duty cycle
45
50
55
1.0
8
%
ns
ns
ns
t , t
Output Rise/Fall Time
Output Disable Time
Output Enable Time
Cycle-to-cycle jitter
0.1
0.55 to 2.4 V
r
f
t
PLZ, HZ
t
10
PZL, LZ
t
output frequencies mixed
all outputs same frequency
150
25
ps
ps
RMS
RMS
JIT(CC)
t
Period Jitter
output frequencies mixed
all outputs same frequency
75
20
ps
ps
RMS
RMS
JIT(PER)
(9)
t
I/O Phase Jitter
÷4 feedback divider RMS (1 σ)
÷6 feedback divider RMS (1 σ)
÷8 feedback divider RMS (1 σ)
÷12 feedback divider RMS (1 σ)
40
40
40
40
ps
ps
ps
ps
JIT(∅)
(10)
BW
PLL closed loop bandwidth
÷4 feedback
÷6 feedback
÷8 feedback
÷12 feedback
2.0–8.0
1.0–4.0
0.8–2.5
0.6–1.5
MHz
MHz
MHz
MHz
t
Maximum PLL Lock Time
10
ms
LOCK
1. AC characteristics apply for parallel output termination of 50 Ω to V
.
TT
2. PLL mode requires PLL_EN=0 to enable the PLL and zero-delay operation.
3. The PLL may be unstable with a divide by 2 feedback ratio.
4. In PLL bypass mode, the MPC93H52 divides the input reference clock.
5. The input frequency f on CCLK must match the VCO frequency range divided by the feedback divider ratio FB: f = f ÷ FB.
ref
ref
VCO
6. See Table 7 and Table 8 for output divider configurations.
7. The MPC93H52 will operate with input rise and fall times up to 3.0 ns, but the AC characteristics, specifically t , can only be guaranteed if
(∅)
t /t are within the specified range.
r
f
8. See application section for part-to-part skew calculation.
9. See application section for a jitter calculation for other confidence factors than 1 σ.
10. –3 dB point of PLL transfer characteristics.
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
5
APPLICATIONS INFORMATION
desired output clock frequencies. Possible frequency ratios
Programming the MPC93H52
of the reference clock input to the outputs are 1:1, 1:2, 1:3,
3:2 as well as 2:3, 3:1 and 2:1. Table 7 illustrates the various
output configurations and frequency ratios supported by the
MPC93H52. See also Table 8 and Figure 3 to Figure 6 for
further reference. A ÷2 output divider cannot be used for
feedback.
The MPC93H52 supports output clock frequencies from
16.67 to 240 MHz. Different feedback and output divider
configurations can be used to achieve the desired input to
output frequency relationship. The feedback frequency and
divider should be used to situate the VCO in the frequency
lock range between 200 and 480 MHz for stable and optimal
operation. The FSELA, FSELB, FSELC pins select the
Table 7. MPC93H52 Example Configuration (F_RANGE = 0)
(1)
PLL
Feedback
fref
FSELA FSELB FSELC
QA[0:4]:fref ratio
(50-120 MHz) fref
QB[0:3]:fref ratio
QC[0:1]:fref ratio
[MHz]
(2)
VCO ÷ 4
50-120
0
0
1
1
1
1
1
1
0
0
0
0
0
0
1
1
0
1
0
1
0
1
0
1
fref
(50-120 MHz) fref ⋅ 2
(100-240 MHz)
(50-120 MHz)
(100-240 MHz)
(50-120 MHz)
(100-240 MHz)
(50-120 MHz)
(100-240 MHz)
(50-120 MHz)
fref
(50-120 MHz) fref
(33-80 MHz) fref
(50-120 MHz) fref
fref ⋅ 2÷3
fref ⋅ 2÷3
fref
(50-120 MHz) fref ⋅ 2
(50-120 MHz) fref
(33-80 MHz) fref
(3)
VCO ÷ 6
33.3-80
(33-80 MHz) fref ⋅3÷2
(33-80 MHz) fref ⋅3÷2
(33-80 MHz) fref ⋅ 3
(33-80 MHz) fref ⋅ 3
(50-120 MHz) fref ⋅ 3
(50-120 MHz) fref ⋅3÷2
(100-240 MHz) fref ⋅ 3
(100-240 MHz) fref ⋅3÷2
fref
fref
fref
1. fref is the input clock reference frequency (CCLK).
2. fref is the input clock reference frequency (CCLK).
3. fref is the input clock reference frequency (CCLK).
Table 8. MPC93H52 Example Configurations (F_RANGE = 1)
(1)
PLL
Feedback
fref
FSELA FSELB FSELC
QA[0:4]:fref ratio
QB[0:3]:fref ratio
QC[0:1]:fref ratio
[MHz]
(2)
VCO ÷ 8
25-60
0
0
1
1
1
1
1
1
0
0
0
0
0
0
1
1
0
1
0
1
0
1
0
1
fref
(25-60 MHz) fref
(25-60 MHz) fref ⋅ 2
(25-60 MHz) fref
(50-120 MHz)
(25-60 MHz)
(50-120 MHz)
(25-60 MHz)
(50-120 MHz)
(25-60 MHz)
(50-120 MHz)
(25-60 MHz)
fref
(25-60 MHz) fref
fref ⋅2÷3
fref ⋅2÷3
fref
(16-40 MHz) fref
(25-60 MHz) fref ⋅ 2
(25-60 MHz) fref
(16-40 MHz) fref
(3)
VCO ÷ 12
16.67-40
(16-40 MHz) fref ⋅3÷2
(16-40 MHz) fref ⋅3÷2
(16-40 MHz) fref ⋅ 3
(16-40 MHz) fref ⋅ 3
(25-60 MHz) fref ⋅ 3
(25-60 MHz) fref ⋅3÷2
(50-120 MHz) fref ⋅ 3
(50-120 MHz) fref ⋅3÷2
fref
fref
fref
1. fref is the input clock reference frequency (CCLK).
2. QAx connected to FB_IN and FSELA=0.
3. QAx connected to FB_IN and FSELA=1.
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
6
Example Configurations for the MPC93H52
QA0
QA0
QA1
QA2
QA3
QA4
fref = 100 MHz
fref = 62.5 MHz
CCLK
FB_IN
CCLK
FB_IN
QA1
QA2
QA3
QA4
100 MHz
62.5 MHz
QB0
QB1
QB2
QB3
QB0
QB1
QB2
QB3
FSELA
FSELB
FSELC
FSELA
FSELB
FSELD
62.5 MHz
62.5 MHz
100 MHz
200 MHz
V
CC
F_RANGE
F_RANGE
QC0
QC1
QC0
QC1
MPC93H52
MPC93H52
100 MHz (Feedback)
62.5 MHz (Feedback)
MPC93H52 default configuration (feedback of QB0 =
100 MHz). All control pins are left open.
MPC93H52 zero-delay (feedback of QB0 = 62.5 MHz). All
control pins are left open except FSELC = 1. All outputs are
locked in frequency and phase to the input clock.
Frequency range
Input
Min
Max
Frequency range
Input
Min
Max
50 MHz
50 MHz
50 MHz
100 MHz
120 MHz
120 MHz
120 MHz
240 MHz
50 MHz
50 MHz
50 MHz
50 MHz
120 MHz
120 MHz
120 MHz
120 MHz
QA outputs
QB outputs
QC outputs
QA outputs
QB outputs
QC outputs
Figure 3. MPC93H52 Default Configuration
Figure 4. MPC93H52 Default Configuration
QA0
QA0
fref = 33.3 MHz
fref = 33.3 MHz
CCLK
CCLK
QA1
QA2
QA3
QA4
QA1
QA2
QA3
QA4
33.3 MHz
33.3 MHz
FB_IN
FB_IN
QB0
QB1
QB2
QB3
QB0
QB1
QB2
QB3
V
V
FSELA
FSELB
FSELC
FSELA
FSELB
FSELC
CC
CC
33.3 MHz
33.3 MHz
50 MHz
V
V
CC
F_RANGE
F_RANGE
V
QC0
QC1
QC0
QC1
CC
CC
100 MHz
MPC93H52
MPC93H52
33.3 MHz (Feedback)
33.3 MHz (Feedback)
MPC93H52 configuration to multiply the reference frequen-
cy by 3, 3÷2 and 1. PLL feedback of QA4 = 33.3 MHz.
MPC93H52 zero-delay (feedback of QB0 = 33.3 MHz).
Equivalent to Table 2 except F_RANGE = 1 enabling a
lower input and output clock frequency.
Frequency range
Input
Min
Max
Frequency range
Input
Min
Max
25 MHz
50 MHz
50 MHz
100 MHz
60 MHz
120 MHz
120 MHz
240 MHz
25 MHz
25 MHz
25 MHz
25 MHz
60 MHz
60 MHz
60 MHz
60 MHz
QA outputs
QB outputs
QC outputs
QA outputs
QB outputs
QC outputs
Figure 5. MPC93H52 Default Configuration
Figure 6. MPC93H52 Default Configuration
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
7
Power Supply Filtering
this section should be adequate to eliminate power supply
noise related problems in most designs.
The MPC93H52 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 MPC93H52
Using the MPC93H52 in Zero-Delay Applications
Nested clock trees are typical applications for the
MPC93H52. Designs using the MPC93H52 as LVCMOS PLL
fanout buffer with zero insertion delay will show significantly
lower clock skew than clock distributions developed from
CMOS fanout buffers. The external feedback option of the
MPC93H52 clock driver allows for its use as a zero delay
buffer. One example configuration is to use a ÷4 output as a
feedback to the PLL and configuring all other outputs to a
divide-by-4 mode. The propagation delay through the device
is virtually eliminated. The PLL aligns the feedback clock
output edge with the clock input reference edge resulting a
near zero delay through the device. The maximum insertion
delay of the device in zero-delay applications is measured
between the reference clock input and any output. This
effective delay consists of the static phase offset, I/O jitter
(phase or long-term jitter), feedback path delay and the
output-to-output skew error relative to the feedback output.
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 MPC93H52. Figure 7 illustrates a typical power
supply filter scheme. The MPC93H52 frequency and phase
stability is most susceptible to noise with spectral content in
the 100 kHz to 20 MHz 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 8 mA (12 mA maximum), assuming that a minimum
of 2.98 V must be maintained on the VCCA pin. The resistor
RF shown in Figure 7 should have a resistance of 5–25 Ω to
meet the voltage drop criteria.
Calculation of Part-to-Part Skew
The MPC93H52 zero delay buffer supports applications
where critical clock signal timing can be maintained across
several devices. If the reference clock inputs of two or more
MPC93H52 are connected together, the maximum overall
timing uncertainty from the common CCLK input to any
output is:
R = 5–25Ω
C = 22 mF
F
F
R
F
V
V
CCA
CC
tSK(PP) = t(∅) + tSK(O) + tPD, LINE(FB) + tJIT(∅) • CF
C
10 nF
F
This maximum timing uncertainty consist of 4 components:
static phase offset, output skew, feedback board trace delay
and I/O (phase) jitter:
MPC93H52
V
CC
33...100 nF
CCLK
Common
t
PD,LINE(FB)
Figure 7. VCCA Power Supply Filter
—t
(∅)
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 7, the filter cut-off frequency is around
3-5 kHz, and the noise attenuation at 100 kHz is better than
42 dB.
QFB
Device 1
Device 1
t
JIT(∅)
Any Q
+t
SK(O)
+t
(∅)
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 MPC93H52 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
QFB
Device2
t
JIT(∅)
Any Q
Device 2
+t
SK(O)
Max. skew
t
SK(PP)
Figure 8. MPC93H51 Maximum Device-to-Device Skew
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
8
Due to the statistical nature of I/O jitter a RMS value (1 σ)
is specified. I/O jitter numbers for other confidence factors
(CF) can be derived from Table 9.
MPC93H52
OUTPUT
BUFFER
Z
= 50Ω
O
R =40Ω
S
Table 9. Confidence Factor CF
10Ω
OutA
IN
IN
CF
Probability of Clock Edge within the Distribution
± 1σ
± 2σ
± 3σ
± 4σ
± 5σ
± 6σ
0.68268948
0.95449988
0.99730007
0.99993663
0.99999943
0.99999999
MPC93H52
OUTPUT
BUFFER
Z
Z
= 50Ω
= 50Ω
O
R =40Ω
S
OutB0
OutB1
10Ω
O
R = 40Ω
S
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, an
I/O jitter confidence factor of 99.7% (± 3σ) is assumed,
resulting in a worst case timing uncertainty from input to any
output of –445 ps to 395 ps relative to CCLK:
Figure 9. Single versus Dual Transmission Lines
The waveform plots in Figure 10 and Figure 11 show the
simulation results of an output driving a single line versus two
lines. In both cases, the drive capability of the MPC93H51
output buffer is more than sufficient to drive 50 Ω
tSK(PP) = [–200ps...150ps] + [–200ps...200ps] +
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 MPC93H51.
The output waveform in Figure 10 and Figure 11 shows a
step in the waveform, this step is caused by the impedance
mismatch seen looking into the driver. The parallel
combination of the 36 Ω 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:
[(15ps • –3)...(15ps • 3)] + tPD, LINE(FB)
tSK(PP) = [–445ps...395ps] + tPD, LINE(FB)
Driving Transmission Lines
The MPC93H52 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 Freescale 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
terminated transmission lines can be used. The parallel
technique terminates the signal at the end of the line with a
50 Ω 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 MPC93H52 clock driver. For the series
terminated case, however, there is no DC current draw, thus
the outputs can drive multiple series terminated lines.
Figure 9 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 MPC93H52
clock driver is effectively doubled due to its capability to drive
multiple lines.
VL = VS (Z0 ÷ (RS + R0 + Z0))
Z0 = 50 Ω || 50 Ω
RS = 40 Ω || 40 Ω
R0 = 10 Ω
VL = 3.0 (25 ÷ (20 + 10 + 25)
= 1.36 V
At the load end, the voltage will double, due to the near
unity reflection coefficient, to 2.7 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).
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 11 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.
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
9
3.0
2.5
2.0
1.5
1.0
0.5
0
MPC93H52
Output
Buffer
Z
Z
= 50Ω
= 50Ω
OutA
t = 3.8956
R = 30Ω
O
O
S
D
OutB
t = 3.9386
D
10Ω
R = 30Ω
S
In
10Ω + 30Ω || 30Ω = 50Ω || 50Ω
25Ω = 25Ω
Figure 11. Optimized Dual Line Termination
2
4
6
8
10
12
14
TIME (nS)
Figure 10. Single versus Dual Waveforms
MPC93H52
DUT
Z
= 50Ω
Z
= 50Ω
Pulse
O
O
Generator
Z = 50Ω
R = 50Ω
R = 50Ω
T
T
V
V
TT
TT
Figure 12. CCLK MPC93H52 AC Test Reference for VCC = 3.3 V and VCC = 2.5 V
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
10
V
V
CC
÷2
V
V
CC
CC
CCLK
FB_IN
÷2
GND
CC
V
V
GND
CC
÷2
CC
V
V
CC
÷2
GND
CC
t
SK(O)
GND
t
(∅)
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 13. Output-to-Output Skew tSK(O)
Figure 14. Propagation Delay (t(∅), status phase offset)
Test Reference
V
V
CC
CCLK
FB_IN
÷2
CC
GND
t
P
T
0
T
= |T -T mean|
0 1
JIT(∅)
DC = t /T x 100%
P
0
The deviation in t for a controlled edge with respect to a t mean
in a random sample of cycles
0
0
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)
Figure 16. I/O Jitter
T
= |T -T
|
N+1
T
= |T -1/f |
JIT(CC)
N
JIT(P)
N
0
T
T
N+1
N
T
0
The variation in cycle time of a signal between adjacent cycles, over a random
sample of adjacent cycle pairs
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
V
=3.3 V
CC
2.4
0.55
t
t
R
F
Figure 19. Output Transition Time Test Reference
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
11
PACKAGE DIMENSIONS
4X
0.20
H
A-B D
6
D1
3
A, B, D
e/2
D1/2
32
PIN 1 INDEX
1
25
F
F
A
B
E1/2
6
E1
E
4
DETAIL G
E/2
DETAIL G
8
17
NOTES:
9
7
1. DIMENSIONS ARE IN MILLIMETERS.
2. INTERPRET DIMENSIONS AND TOLERANCES PER
ASME Y14.5M, 1994.
3. DATUMS A, B, AND D TO BE DETERMINED AT
DATUM PLANE H.
D
4
D/2
4X
D
4. DIMENSIONS D AND E TO BE DETERMINED AT
SEATING PLANE C.
0.20
C
A-B D
5. DIMENSION b DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR PROTRUSION
SHALL NOT CAUSE THE LEAD WIDTH TO EXCEED
THE MAXIMUM b DIMENSION BY MORE THAN
0.08-mm. DAMBAR CANNOT BE LOCATED ON THE
LOWER RADIUS OR THE FOOT. MINIMUM SPACE
BETWEEN PROTRUSION AND ADJACENT LEAD OR
PROTRUSION: 0.07-mm.
H
28X e
32X
0.1 C
6. DIMENSIONS D1 AND E1 DO NOT INCLUDE MOLD
PROTRUSION. ALLOWABLE PROTRUSION IS
0.25-mm PER SIDE. D1 AND E1 ARE MAXIMUM
PLASTIC BODY SIZE DIMENSIONS INCLUDING
MOLD MISMATCH.
7. EXACT SHAPE OF EACH CORNER IS OPTIONAL.
8. THESE DIMENSIONS APPLY TO THE FLAT
SECTION OF THE LEAD BETWEEN 0.1-mm AND
0.25-mm FROM THE LEAD TIP.
SEATING
PLANE
C
DETAIL AD
BASE
METAL
PLATING
b1
c
c1
MILLIMETERS
DIM
A
A1
A2
b
b1
c
c1
D
MIN
1.40
0.05
1.35
0.30
0.30
0.09
0.09
MAX
1.60
0.15
1.45
0.45
0.40
0.20
0.16
b
5
8
8X (θ1˚)
M
0.20
C
A-B
D
R R2
SECTION F-F
R R1
0.25
9.00 BSC
D1
e
E
E1
L
L1
q
q1
R1
R2
S
7.00 BSC
0.80 BSC
9.00 BSC
7.00 BSC
A2
A
GAUGE PLANE
0.50
1.00 REF
0˚ 7˚
12 REF
0.70
(S)
A1
L
θ˚
0.08
0.08
0.20
---
(L1)
0.20 REF
DETAIL AD
CASE 873A-03
ISSUE B
32-LEAD LQFP PACKAGE
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
12
NOTES
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
13
NOTES
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
14
NOTES
MPC93H52
Advanced Clock Drivers Devices
Freescale Semiconductor
15
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MPC93H52
Rev. 5
1/2005
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