MOTOROLA
SEMICONDUCTOR TECHNICAL DATA
Order Number: MPC9229/D
Rev 1 03/2003
Motorola, Inc. 2003
400 MHz Low Voltage PECL
Clock Synthesizer
The MPC9229 is a 3.3V compatible, PLL based clock synthesizer
targeted for high performance clock generation in mid-range to
high-performance telecom, networking and computing applications. With
output frequencies from 25 MHz to 400 MHz and the support of differential
PECL output signals the device meets the needs of the most demanding
clock applications.
Features
25 MHz to 400 MHz synthesized clock output signal
Differential PECL output
LVCMOS compatible control inputs
On-chip crystal oscillator for reference frequency generation
3.3V power supply
Fully integrated PLL
Minimal frequency overshoot
Serial 3-wire programming interface
Parallel programming interface for power-up
32 lead LQFP and 28 PLCC packaging
SiGe Technology
Ambient temperature range 0°Cto+70°C
Pin and function compatible to the MC12429
Functional Description
The internal crystal oscillator uses the external quartz crystal as the
basis of its frequency reference. The frequency of the internal crystal
oscillator is divided by 16 and then multiplied by the PLL. The VCO within
the PLL operates over a range of 800 to 1600 MHz. Its output is scaled by
a divider that is configured by either the serial or parallel interfaces. The
crystal oscillator frequency fXTAL, the PLL feedback-divider M and the PLL
post-divider N determine the output frequency.
The feedback path of the PLL is internal. The PLL adjusts the VCO output frequency to be 4M times the reference frequency
by adjusting the VCO control voltage. Note that for some values of M (either too high or too low) the PLL will not achieve phase
lock. The PLL will be stable if the VCO frequency is within the specified VCO frequency range (800 to 1600 MHz). The M-value
must be programmed by the serial or parallel interface.
The PLL post-divider N is configured through either the serial or the parallel interfaces, and can provide one of four division
ratios (1, 2, 4, or 8). This divider extends performance of the part while providing a 50% duty cycle. The output driver is driven
differentially from the output divider, and is capable of driving a pair of transmission lines terminated 50to VCC –2.0V.The
positive supply voltage for the internal PLL is separated from the power supply for the core logic and output drivers to minimize
noise induced jitter.
The configuration logic has two sections: serial and parallel. The parallel interface uses the values at the M[8:0] and N[1:0]
inputs to configure the internal counters. It is recommended on system reset to hold the P_LOAD input LOW until power becomes
valid. On the LOW–to–HIGH transition of P_LOAD, the parallel inputs are captured. The parallel interface has priority over the
serial interface. Internal pullup resistors are provided on the M[8:0] and N[1:0] inputs prevent the LVCMOS compatible control
inputs from floating.
The serial interface centers on a fourteen bit shift register. The shift register shifts once per rising edge of the S_CLOCK input.
The serial input S_DATA must meet setup and hold timing as specified in the AC Characteristics section of this document. The
configuration latches will capture the value of the shift register on the HIGH–to–LOW edge of the S_LOAD input. See the
programming section for more information. The TEST output reflects various internal node values, and is controlled by the T[2:0]
bits in the serial data stream. In order to minimize the PLL jitter, it is recommended to avoid active signal on the TEST output.
FA SUFFIX
32 LEAD LQFP PACKAGE
CASE 873A
MPC9229
400 MHZ LOW VOLTAGE
CLOCK SYNTHESIZER
FN SUFFIX
28--LEAD PLCC PACKAGE
CASE 776
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MPC9229
MOTOROLA TIMING SOLUTIONS2
Figure 1. MPC9229 Logic Diagram
GND
TEST
VCC
VCC
GND
FOUT
FOUT
NC
M[3]
M[2]
M[1]
M[0]
P_LOAD
NC
N[1]
N[0]
M[8]
M[7]
M[6]
M[5]
M[4]
S_CLOCK
S_LOAD
VCC_PLL
VCC_PLL
NC
NC
XTAL_IN
25
26
27
28
29
30
31
32
15
14
13
12
11
10
9
12345678
24 23 22 21 20 19 18 17
16
Figure 2. MPC9229 28--Lead PLCC Pinout
(Top View)
VCC
OE
XTAL_OUT
XTAL_IN
XTAL_OUT
S_LOAD
÷16
S_DATA
S_CLOCK
M[0:8]
XTAL
PLL
Ref
FB
VCO
800-1600 MHz
00
01
10
11
÷0to÷511
9-Bit M-Divider
M-Latch N-Latch
10 -- 20 MHz
T-Latch
92
Te s t
3
LE
00
Bit 5-13 Bit 3-4 Bit 0-2
14 Bit Shift Register
Sync
N[1:0]
OE
P/S
÷1
÷2
÷4
÷8
FOUT
FOUT
TEST
VCC
VCC
P_LOAD
÷4
OE
1
4
3
2
28
27
26
25 24 23 22 21 20 19
18
17
16
15
14
13
12
11109
78
65
Figure 3. MPC9229 32--Lead LQFP Pinout
(Top View)
VCCXTAL_OUT
P_LOAD
OE
M[0]
M[1]
M[2]
M[3]
FOUT
FOUT
GND
VCC
TEST
GND
S_CLOCK N[1]
N[0]
M[8]
M[7]
M[6]
M[5]
M[4]
S_DATA
S_LOAD
VCC_PLL
NC
NC
XTAL_IN
11
S_DATA
MPC9229
MPC9229
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MPC9229
TIMING SOLUTIONS 3 MOTOROLA
Table 1. Pin Configuration
Pin I/O Default Type Function
XTAL_IN, XTAL_OUT Analog Crystal oscillator interface
FOUT, FOUT Output LVPECL Differential clock output
TEST Output LVCMOS Test and device diagnosis output
S_LOAD Input 0LVCMOS Serial configuration control input.
This inputs controls the loading of the configuration latches with the contents of
the shift register. The latches will be transparent when this signal is high, thus the
data must be stable on the high-to-low transition.
P_LOAD Input 1LVCMOS Parallel configuration control input.
This input controls the loading of the configuration latches with the content of the
parallel inputs (M and N). The latches will be transparent when this signal is low,
thus the parallel data must be stable on the low-to-high transition of P_LOAD.
P_LOAD is state sensitive
S_DATA Input 0LVCMOS Serial configuration data input.
S_CLOCK Input 0LVCMOS Serial configuration clock input.
M[0:8] Input 1LVCMOS Parallel configuration for PLL feedback divider (M).
M is sampled on the low-to-high transition of P_LOAD.
N[1:0] Input 1LVCMOS Parallel configuration for Post-PLL divider (N).
N is sampled on the low-to-high transition of P_LOAD
OE Input 1LVCMOS Output enable (active high)
The output enable is synchronous to the output clock to eliminate the possibility of
runt pulses on the FOUT output. OE = L low stops FOUT in the logic low state
(FOUT =L,FOUT=H)
GND Supply Supply Ground Negative power supply (GND)
VCC Supply Supply VCC Positive power supply for I/O and core. All VCC pins must be connected to the
positive power supply for correct operation
VCC_PLL Supply Supply VCC PLL positive power supply (analog power supply)
Table 2. Output frequency range and PLL Post-divider N
N
O
d
i
i
i
O
f
1 0 Output division Output frequency range
0 0 1 200 - 400 MHz
0 1 2 100 - 200 MHz
1 0 4 50 - 100 MHz
1 1 8 25 - 50 MHz
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MOTOROLA TIMING SOLUTIONS4
Table 3. General Specifications
Symbol Characteristics Min Typ Max Unit Condition
VTT Output Termination Voltage VCC -2 V
MM ESD protection (Machine Model) 200 V
HBM ESD protection (Human Body Model) 2000 V
LU Latch-Up Immunity 200 mA
CIN Input Capacitance 4.0 pF Inputs
θJA LQFP 32 Thermal resistance junction to ambient
JESD 51-3, single layer test board
JESD 51-6, 2S2P multilayer test board
83.1
73.3
68.9
63.8
57.4
59.0
54.4
52.5
50.4
47.8
86.0
75.4
70.9
65.3
59.6
60.6
55.7
53.8
51.5
48.8
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
Natural convection
100 ft/min
200 ft/min
400 ft/min
800 ft/min
Natural convection
100 ft/min
200 ft/min
400 ft/min
800 ft/min
θJC LQFP 32 Thermal resistance junction to case 23.0 26.3 °C/W MIL-SPEC 883E
Method 1012.1
Table 4. Absolute Maximum Ratingsa
Symbol Characteristics Min Max Unit Condition
VCC Supply Voltage -0.3 3.9 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
TSStorage Temperature -65 125 °C
a. 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 =3.3V ±5%, TA=0°Cto+70°C)
Symbol Characteristics Min Typ Max Unit Condition
LVCMOS control inputs (P_LOAD, S_LOAD, S_DATA, S_CLOCK, M[0:8], N[0:1], OE)
VIH Input High Voltage 2.0 VCC +0.3 VLVCMOS
VIL Input Low Voltage 0.8 VLVCMOS
IIN Input Currenta±200 µA VIN =V
CC or GND
Differential clock output FOUTb
VOH Output High VoltagecVCC--1.02 VCC--0.74 VLVPECL
VOL Output Low VoltagecVCC--1.95 VCC--1.60 VLVPECL
Test and diagnosis output TEST
VOH Output High Voltagec2.0 V IOH =-0.8mA
VOL Output Low Voltagec0.55 V IOL =0.8mA
Supply current
ICC_PLL Maximum PLL Supply Current 20 mA VCC_PLL Pins
ICC Maximum Supply Current 100 mA All VCC Pins
a. Inputs have pull-down resistors affecting the input current.
b. Outputs terminated 50to VTT =V
CC -2V.
c. The MPC9229 TEST output levels are compatible to the MC12429 output levels.
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MPC9229
TIMING SOLUTIONS 5 MOTOROLA
Table 6. AC Characteristics (VCC =3.3V ±5%, TA=0°Cto+70°C)a
Symbol Characteristics Min Typ Max Unit Condition
fXTAL Crystal interface frequency range 10 20 MHz
fVCO VCO frequency rangeb800 1600 MHz
fMAX Output Frequency N = 00 (÷1)
N=01(÷2)
N=10(÷4)
N=11(÷8)
200
100
50
25
400
200
100
50
MHz
MHz
MHz
MHz
DC Output duty cycle 45 50 55 %
tr,t
fOutput Rise/Fall Time 0.05 0.3 ns 20% to 80%
fS_CLOCK Serial interface programming clock frequencyc010 MHz
tP, MI N Minimum pulse width (S_LOAD, P_LOAD)50 ns
tSSetup Time S_DATA to S_CLOCK
S_CLOCK to S_LOAD
M, N to P_LOAD
20
20
20
ns
ns
ns
tSHold Time S_DATA to S_CLOCK
M, N to P_LOAD
20
20
ns
ns
tJIT(CC) Cycle--to--cycle jitter N = 00 (÷1)
N=01(÷2)
N=10(÷4)
N=11(÷8)
90
130
160
190
ps
ps
ps
ps
tJIT(PER) Period Jitter N = 00 (÷1)
N=01(÷2)
N=10(÷4)
N=11(÷8)
70
120
140
170
ps
ps
ps
ps
tLOCK Maximum PLL Lock Time 10 ms
a. AC characteristics apply for parallel output termination of 50to VTT.
b. The input frequency fXTAL and the PLL feedback divider M must match the VCO frequency range: fVCO =f
XTAL M÷4.
c. The frequency of S_CLOCK is limited to 10 MHz in serial programming mode. S_CLOCK can be switched at higher frequencies when used
as test clock in test mode 6. See application section for more details.
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MOTOROLA TIMING SOLUTIONS6
Programming the MPC9229
Programming the MPC9229 amounts to properly
configuring the internal PLL dividers to produce the desired
synthesized frequency at the output. The output frequency
can be represented by this formula:
fOUT =(f
XTAL ÷16) (4 M) ÷(4 N) or (1)
fOUT =(f
XTAL ÷16) M÷N(2)
where fXTAL is the crystal frequency, M is the PLL
feedback-divider and N is the PLL post-divider. The input
frequency and the selection of the feedback divider M is limited
by the VCO-frequency range. fXTAL and M must be configured
to match the VCO frequency range of 800 to 1600 MHz in
order to achieve stable PLL operation:
MMIN =4fVCO,MIN ÷fXTAL and (3)
MMAX =4fVCO,MAX ÷fXTAL (4)
For instance, the use of a 16 MHz input frequency requires
the configuration of the PLL feedback divider between M=200
and M = 400. Table 7 shows the usable VCO frequency and
M divider range for other example input frequencies.
Assuming that a 16 MHz input frequency is used, equation (2)
reduces to:
fOUT =M÷N(5)
Table 7. MPC9229 Frequency Operating Range
VCO frequency for an crystal interface frequency of Output frequency for fXTAL=16 MHz and for N =
MM[8:0] 10 12 14 16 18 20 1 2 4 16
160 010100000 800
170 010101010 850
180 010110100 810 900
190 010111110 855 950
200 011001000 800 900 1000 200 100 50 25
210 011010010 840 945 1050 210 105 52.5 26.25
220 011011100 880 990 1100 220 110 55 27.50
230 011100110 805 920 1035 1150 230 115 57.5 28.75
240 011110000 840 960 1080 1200 240 120 60 30
250 011111010 875 100 1125 1250 250 125 62.5 31.25
260 100000100 910 1040 1170 1300 260 130 65 32.50
270 100001110 810 945 1080 1215 1350 270 135 67.5 33.75
280 100011000 840 980 1120 1260 1400 280 140 70 35
290 100100010 870 1015 1160 1305 1450 290 145 72.5 36.25
300 100101100 900 1050 1200 1350 1500 300 150 75 37.5
310 100110110 930 1085 1240 1395 1550 310 155 77.5 38.75
320 101000000 800 960 1120 1280 1440 1600 320 160 80 40
330 101001010 825 990 1155 1320 1485 330 165 82.5 41.25
340 101010100 850 1020 1190 1360 1530 340 170 85 42.5
350 101011110 875 1050 1225 1400 1575 350 175 87.5 43.75
360 101101000 900 1080 1260 1440 360 180 90 45
370 101110010 925 1110 1295 1480 370 185 92.5 46.25
380 101111100 950 1140 1330 1520 380 190 95 47.5
390 110000110 975 1170 1365 1560 390 195 97.5 48.75
400 110010000 1000 1200 1400 1600 400 200 100 50
410 110011010 1025 1230 1435
420 110100100 1050 1260 1470
430 110101110 1075 1290 1505
440 110111000 1100 1320 1540
450 111000010 1125 1350 1575
510 111111110 1275 1530
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TIMING SOLUTIONS 7 MOTOROLA
Substituting N for the four available values for N (1, 2, 4, 8)
yields:
Table 8. Output Frequency Range for fXTAL =16MHz
NFOUT FOUT range FOUT step
1 0 Value
O
U
T
O
U
T
g
O
U
T
p
0 0 1 M 200 - 400 MHz 1MHz
0 1 2 M÷2100 - 200 MHz 500 kHz
1 0 4 M÷450 - 100 MHz 250 kHz
1 1 8 M÷825 - 50 MHz 125 kHz
Example frequency calculation for an 16 MHz input
frequency
If an output frequency of 131 MHz was desired the following
steps would be taken to identify the appropriate M and N
values. According to Table 8, 131 MHz falls in the frequency
set by an value of 2 so N[1:0] = 01. For N = 2 the output
frequency is FOUT =M÷2 and M = FOUT x 2. Therefore M =
2 x 131 = 262, so M[8:0] = 100000110. Following this
procedure a user can generate any whole frequency between
25 MHz and 400 MHz. Note than for N > 2 fractional values of
can be realized. The size of the programmable frequency
steps (and thus the indicator of the fractional output
frequencies achievable) will be equal to:
fSTEP =f
XTAL ÷16 ÷N(6)
Using the parallel and serial interface
The M and N counters can be loaded either through a
parallel or serial interface. The parallel interface is controlled
via the P_LOAD signal such that a LOW to HIGH transition will
latch the information present on the M[8:0] and N[1:0] inputs
into the M and N counters. When the P_LOAD signal is LOW
the input latches will be transparent and any changes on the
M[8:0] and N[1:0] inputs will affect the FOUT output pair. To
use the serial port the S_CLOCK signal samples the
information on the S_DATA line and loads it into a 14 bit shift
register. Note that the P_LOAD signal must be HIGH for the
serial load operation to function. The Test register is loaded
with the first three bits, the N register with the next two and the
M register with the final eight bits of the data stream on the
S_DATA input. For each register the most significant bit is
loaded first (T2, N1 and M8). A pulse on the S_LOAD pin after
the shift register is fully loaded will transfer the divide values
into the counters. The HIGH to LOW transition on the S_LOAD
input will latch the new divide values into the counters. Figure
4 illustrates the timing diagram for both a parallel and a serial
load of the MPC9229 synthesizer. M[8:0] and N[1:0] are
normally specified once at power–up through the parallel
interface, and then possibly again through the serial interface.
This approach allows the application to come up at one
frequency and then change or fine–tune the clock as the ability
to control the serial interface becomes available.
Using the test and diagnosis output TEST
The TEST output provides visibility for one of the several
internal nodes as determined by the T[2:0] bits in the serial
configuration stream. It is not configurable through the parallel
interface. Although it is possible to select the node that
represents FOUT
, the CMOS output is not able to toggle fast
enough for higher output frequencies and should only be used
for test and diagnosis. The T2, T1 and T0 control bits are
preset to ‘000’ when P_LOAD is LOW so that the PECL FOUT
outputs are as jitter–free as possible. Any active signal on the
TEST output pin will have detrimental affects on the jitter of the
PECL output pair. In normal operations, jitter specifications are
only guaranteed if the TEST output is static. The serial
configuration port can be used to select one of the alternate
functions for this pin. Mostof the signals available on the TEST
output pin are useful only for performance verification of the
MPC9229 itself. However the PLL bypass mode may be of
interest at the board level for functional debug. When T[2:0] is
set to 110 the MPC9229 is placed in PLL bypass mode. In this
mode the S_CLOCK input is fed directly into the M and N
dividers. The N divider drives the FOUT differential pair and the
M counter drives the TEST output pin. In this mode the
S_CLOCK input could be used for low speed board level
functional test or debug. Bypassing the PLL and driving FOUT
directly gives the user more control on the test clocks sent
through the clock tree. Figure 6 shows the functional setup of
the PLL bypass mode. Because the S_CLOCK is a CMOS
level the input frequency is limited to 200 MHz. This means the
fastest the FOUT pin can be toggled via the S_CLOCK is 100
MHz as the divide ratio of the Post-PLL divider is 2 (if N = 1).
Note that the M counter output on the TEST output will not be
a 50% duty cycle.
Table 9. Test and Debug Configuration for TEST
T[2:0] TEST output
T2 T1 T0
p
0 0 0 14-bit shift register outa
0 0 1 Logic 1
0 1 0 fXTAL ÷16
0 1 1 M-Counter out
1 0 0 FOUT
1 0 1 Logic 0
1 1 0 M-Counter out in PLL-bypass mode
1 1 1 FOUT ÷4
a. Clocked out at the rate of S_CLOCK
Table 10. Debug Configuration for PLL bypassa
Output Configuration
FOUT S_CLOCK ÷N
TEST M-Counter outb
a. T[2:0]=110. AC specifications do not apply in PLL bypass
mode
b. clocked out at the rate of S_CLOCK÷(4N)
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MOTOROLA TIMING SOLUTIONS8
Figure 4. Serial Interface Timing Diagram
S_CLOCK
S_DATA
S_LOAD
M[8:0]
N[1:0]
P_LOAD
T2 T1 T0 N1 N0 M8 M7 M6 M5 M4 M3 M2 M1 M0
M, N
First
Bit
Last
Bit
Power Supply Filtering
The MPC9229 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 VCC_PLL pin impacts the device characteristics. The
MPC9229 provides separate power supplies for the digital
circuitry (VCC) and the internal PLL (VCC_PLL) of the device.
The purpose of this design technique is to try and isolate the
high switching noise digital outputs from the relatively
sensitive internal analog phase–locked loop. In a controlled
environment such as an evaluation board, this level of
isolation is sufficient. However, 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
simplest form of isolation is a power supply filter on the
VCC_PLL pin for the MPC9229. Figure 5 illustrates a typical
power supply filter scheme. The MPC9229 is mostsusceptible
to noise with spectral content in the 1 kHz to 1 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 that will be seen between the VCC
supply and the MPC9229 pin of the MPC9229. From the data
sheet, the VCC_PLL current (the current sourced through the
VCC_PLL pin) is maximum 20 mA, assuming that a minimum
of 2.835 V must be maintained on the VCC_PLL pin. The
resistor shown in Figure 5 must have a resistance of 10-15
to meet the voltage drop criteria. The RC filter pictured will
provide a broadband filter with approximately 100:1
attenuation for noise whose spectral content is above 20 kHz.
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. Generally, the resistor/capacitor
filter will be cheaper, easier to implement and provide an
adequate level of supply filtering. A higher level of attenuation
can be achieved by replacing the resistor with an appropriate
valued inductor. A 1000 µH choke will show a significant
impedance at 10 kHz frequencies and above. Because of the
current draw and the voltage that must be maintained on the
VCC_PLL pin, a low DC resistance inductor is required (less
than 15 ).
Figure 5. VCC PLL Power Supply Filter
VCC_PLL
VCC
MPC9229
C1,C
2= 0.01...0.1 µF
VCC
CF=22µF
RF=10--15
C2
C1
Layout Recommendations
The MPC9229 provides sub–nanosecond output edge
rates and thus a good power supply bypassing scheme is a
must. Figure 6 shows a representative board layout for the
MPC9229. There exists many different potential board layouts
and the one pictured is but one. The important aspect of the
layout in Figure 6 is the low impedance connections between
VCC and GND for the bypass capacitors. Combining good
quality general purpose chip capacitors with good PCB layout
techniques will produce effective capacitor resonances at
frequencies adequate to supply the instantaneous switching
current for the MPC9229 outputs. It is imperative that low
inductance chip capacitors are used; it is equally important
that the board layout does not introduce back all of the
inductance saved by using the leadless capacitors. Thin
interconnect traces between the capacitor and the power
plane should be avoided and multiple large vias should be
used to tie the capacitors to the buried power planes. Fat
interconnect and large vias will help to minimize layout
induced inductance and thus maximize the series resonant
point of the bypass capacitors. Note the dotted lines circling
the crystal oscillator connection to the device. The oscillator is
a series resonant circuit and the voltage amplitude across the
crystal is relatively small. It is imperative that no actively
switching signals cross under the crystal as crosstalk energy
coupled to these lines could significantly impact the jitter of the
device. Special attention should be paid to the layout of the
crystal to ensure a stable, jitter free interface between the
crystal and the on–board oscillator. Although the MPC9229
has several design features to minimize the susceptibility to
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TIMING SOLUTIONS 9 MOTOROLA
power supply noise (isolated power and grounds and fully
differential PLL), there still may be applications in whichoverall
performance is being degraded due to system power supply
noise. The power supply filter and bypass schemes discussed
in this section should be adequate to eliminate power supply
noise related problems in most designs.
Figure 6. PCB Board Layout Recommendation for
the PLCC28 Package
C2
1
CF
Xtal
C1 C1
=V
CC
=GND
=Via
Using the On--Board Crystal Oscillator
The MPC9229 features a fully integrated on--board crystal
oscillator to minimize system implementation costs. The
oscillator is a series resonant, multivibrator type design as
opposed to the more common parallel resonant oscillator
design. The series resonant design provides better stability
and eliminates the need for large on chip capacitors. The
oscillator is totally self contained so that the only external
component required is the crystal. As the oscillator is
somewhat sensitive to loading on its inputs the user is advised
to mount the crystal as close to the MPC9229 as possible to
avoid any board level parasitics. To facilitate co--location
surface mount crystals are recommended, but not required.
Because the series resonant design is affected by capacitive
loading on the xtal terminals loading variation introduced by
crystals from different vendors could be a potential issue. For
crystals with a higher shunt capacitance it may be required to
place a resistance across the terminals to suppress the third
harmonic. Although typically not required it is a good idea to
layout the PCB with the provision of adding this external
resistor. The resistor value will typically be between 500 and
1K.
The oscillator circuit is a series resonant circuit and thus for
optimum performance a series resonant crystal should be
used. Unfortunately most crystals are characterized in a
parallel resonant mode. Fortunately there is no physical
difference between a series resonant and a parallel resonant
crystal. The difference is purely in the way the devices are
characterized. As a result a parallel resonant crystal can be
used with the MPC9229 with only a minor error in the desired
frequency. A parallel resonant mode crystal used in a series
resonant circuit will exhibit a frequency of oscillation a few
hundred ppm lower than specified, a few hundred ppm
translates to kHz inaccuracies. In a general computer
application this level of inaccuracy is immaterial. Table 11
below specifies the performance requirements of the crystals
to be used with the MPC9229.
Table 11. Recommended Crystal Specifications
Parameter Value
Crystal Cut Fundamental AT Cut
Resonance Series Resonance*
Frequency Tolerance ±75ppm at 25°C
Frequency/Temperature Stability ±150pm 0 to 70°C
Operating Range 0to70°C
Shunt Capacitance 5--7pF
Equivalent Series Resistance (ESR) 50 to 80
Correlation Drive Level 100µW
Aging 5ppm/Yr (First 3 Years)
* See accompanying text for series versus parallel resonant
discussion.
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MPC9229
MOTOROLA TIMING SOLUTIONS10
OUTLINE DIMENSIONS
FN SUFFIX
PLASTIC PLCC PACKAGE
CASE 776--02
ISSUE D
NOTES:
1. DATUMS --L--, --M--, AND --N-- DETERMINED
WHERE TOP OF LEAD SHOULDER EXITS
PLASTIC BODY AT MOLD PARTING LINE.
2. DIMENSION G1, TRUE POSITION TO BE
MEASURED AT DATUM --T--, SEATING PLANE.
3. DIMENSIONS R AND U DO NOT INCLUDE
MOLD FLASH. ALLOWABLE MOLD FLASH IS
0.010 (0.250) PER SIDE.
4. DIMENSIONING AND TOLERANCING PER
ANSI Y14.5M, 1982.
5. CONTROLLING DIMENSION: INCH.
6.THEPACKAGETOPMAYBESMALLERTHAN
THEPACKAGEBOTTOMBYUPTO0.012
(0.300). DIMENSIONS R AND U ARE
DETERMINED AT THE OUTERMOST
EXTREMES OF THE PLASTIC BODY
EXCLUSIVE OF MOLD FLASH, TIE BAR
BURRS, GATE BURRS AND INTERLEAD
FLASH, BUT INCLUDING ANY MISMATCH
BETWEEN THE TOP AND BOTTOM OF THE
PLASTIC BODY.
7. DIMENSION H DOES NOT INCLUDE DAMBAR
PROTRUSION OR INTRUSION. THE DAMBAR
PROTRUSION(S) SHALL NOT CAUSE THE H
DIMENSION TO BE GREATER THAN 0.037
(0.940). THE DAMBAR INTRUSION(S) SHALL
NOT CAUSE THE H DIMENSION TO BE
SMALLER THAN 0.025 (0.635).
-- N --
-- M --
-- L --
V
WD
D
Y BRK
28 1
VIEW S
S
L--M
S
0.010 (0.250) N S
T
S
L--M
M
0.007 (0.180) N S
T
0.004 (0.100)
G1
GJ
C
Z
R
E
A
SEATING
PLANE
S
L--M
M
0.007 (0.180) N S
T
-- T --
B
S
L--M
S
0.010 (0.250) N S
T
S
L--M
M
0.007 (0.180) N S
T
U
S
L--M
M
0.007 (0.180) N S
T
Z
G1X
VIEW D--D
S
L--M
M
0.007 (0.180) N S
T
K1
VIEW S
H
K
FS
L--M
M
0.007 (0.180) N S
T
DIM MIN MAX MIN MAX
MILLIMETERSINCHES
A0.485 0.495 12.32 12.57
B0.485 0.495 12.32 12.57
C0.165 0.180 4.20 4.57
E0.090 0.110 2.29 2.79
F0.013 0.019 0.33 0.48
G0.050 BSC 1.27 BSC
H0.026 0.032 0.66 0.81
J0 . 0 2 0 -- -- -- 0 . 5 1 -- -- --
K0 . 0 2 5 -- -- -- 0 . 6 4 -- -- --
R0.450 0.456 11.43 11.58
U0.450 0.456 11.43 11.58
V0.042 0.048 1.07 1.21
W0.042 0.048 1.07 1.21
X0.042 0.056 1.07 1.42
Y-- -- -- 0 . 0 2 0 -- -- -- 0 . 5 0
Z210 210
G1 0.410 0.430 10.42 10.92
K1 0 . 0 4 0 -- -- -- 1 . 0 2 -- -- --
__ __
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MPC9229
TIMING SOLUTIONS 11 MOTOROLA
OUTLINE DIMENSIONS
FA SUFFIX
LQFP PACKAGE
CASE 873A-03
ISSUE B
12 REF
D1
D/2
EE1
1
8
9
17
25
32
F
F
e/2
DETAIL G
BASE
c1c
b
b1
METAL
SECTION F--F
e
SEATING
PLANE
RR2
_
(S) L
(L1)
0.25
GAUGE PLANE
A2
A
A1
DETAIL AD
DETAIL AD
D1/2
E1/2
E/2
4X
D
7
A
D
B
A--B0.20 H
0.1 C
(1)
_
8X
A, B, D
A--B
M
0.20 DC
NOTES:
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.
4. DIMENSIONS D AND E TO BE DETERMINED AT
SEATING PLANE C.
5. DIMENSION b DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR PROTRUSION
SHALL NOT CAUSE THE LEAD WIDTH TO EXCEED
THEMAXIMUMbDIMENSIONBYMORETHAN
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.
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.
DIM MIN MAX
MILLIMETERS
A
A1
7.00 BSC
A2
0.80 BSC
b
9.00 BSC
b1 0.30 0.40
c0.09 0.20
c1 0.09 0.16
D
D1
e
E
E1
L
L1 1.00 REF
R1 0.08 0.20
R2
S
1
1.40 1.60
0.05 0.15
1.35 1.45
0.30 0.45
0 . 0 8 -- -- --
07
__
_
9.00 BSC
7.00 BSC
0.50 0.70
θ
θ
0.20 REF
D
4X
A--B0.20 C D
6
6 4
4
DETAIL G
PIN 1 INDEX
C
32X
28X
H
5 8
PLATING
3
θ
θ
RR1
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MPC9229
MOTOROLA TIMING SOLUTIONS12
Information in this document is provided solely to enable system and software implementers to use Motorola products. There are no express or implied copyright
licenses granted hereunder to design or fabricate any integrated circuits or integrated circuits based on the information in this document.
Motorola reserves the right to make changes without further notice to any products herein. Motorola makes no warranty, representation or guarantee regarding
the suitability of its products for any particular purpose, nor does Motorola assume any liability arising out of the application or use of any product or circuit, and
specifically disclaims any and all liability, including without limitation consequential or incidental damages. “Typical” parameters which may be provided in Motorola
data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals”
must be validated for each customer application by customer’s technical experts. Motorola does not convey any license under its patent rights nor the rights of
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applications intended to support or sustain life, or for any other application in which the failure of the Motorola product could create a situation where personal injury
or death may occur. Should Buyer purchase or use Motorola products for any such unintended or unauthorized application, Buyer shall indemnify and holdMotorola
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MOTOROLA and the Stylized M Logo are registered in the US Patent and Trademark Office. All other product or service names are the property of their respective
owners.
EMotorola Inc. 2003
HOW TO REACH US:
USA/EUROPE/LOCATIONS NOT LISTED:ASIA/PACIFIC: Motorola Semiconductors H.K. Ltd.; Silicon Harbour Centre,
2, Dai King Street, Tai Po Industrial Estate, Tai Po, N.T., Hong Kong.
TECHNICAL INFORMATION CENTER: 852--26668334
1--800--521--6274 or 480--768--2130
HOME PAGE: http://motorola.com/semiconductors
JAPAN: Motorola Japan Ltd.; SPS, Technical Information Center,
3--20--1, Minami--Azabu, Minato--ku, Tokyo 106--8573 Japan
81--3--3440--3569
MPC9229/D
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