MOTOROLA MC145170D2

Freescale Semiconductor, Inc.
Technical Data
MC145170-2/D
Rev. 4, 02/2003
MC145170-2
PLL Frequency
Synthesizer with Serial
Interface
P SUFFIX
CASE 648
Freescale Semiconductor, Inc...
D SUFFIX
CASE 751B
DT SUFFIX
CASE 948C
Ordering Information
Device
Operating
Temp Range
Plastic DIP
MC145170P2
MC145170D2
MC145170DT2
Contents:
1
2
3
4
5
Introduction . . . . . . . . . . 1
Specifications . . . . . . . . 3
Pin Connections . . . . . 10
Design Considerations 18
Packaging. . . . . . . . . . . 30
Package
TA = -40 to 85°C
SOG-16
TSSOP-16
1 Introduction
The new MC145170-2 is pin-for-pin compatible with the MC145170-1. A comparison of the
two parts is shown in the table below. The MC145170-2 is recommended for new designs
and has a more robust power-on reset (POR) circuit that is more responsive to momentary
power supply interruptions. The two devices are actually the same chip with mask options for
the POR circuit. The more robust POR circuit draws approximately 20 µA additional supply
current. Note that the maximum specification of 100 µA quiescent supply current has not
changed.
The MC145170-2 is a single-chip synthesizer capable of direct usage in the MF, HF, and
VHF bands. A special architecture makes this PLL easy to program. Either a bit- or byteoriented format may be used. Due to the patented BitGrabber registers, no address/steering
bits are required for random access of the three registers. Thus, tuning can be accomplished
via a 2-byte serial transfer to the 16-bit N register.
The device features fully programmable R and N counters, an amplifier at the fin pin, on-chip
support of an external crystal, a programmable reference output, and both single- and doubleended phase detectors with linear transfer functions (no dead zones). A configuration (C)
register allows the part to be configured to meet various applications. A patented feature
allows the C register to shut off unused outputs, thereby minimizing noise and interference.
In order to reduce lock times and prevent erroneous data from being loaded into the counters,
a patented jam-load feature is included. Whenever a new divide ratio is loaded into the N
register, both the N and R counters are jam-loaded with their respective values and begin
counting down together. The phase detectors are also initialized during the jam load.
•
Operating Voltage Range: 2.7 to 5.5 V
© Motorola, Inc., 2003. All rights reserved.
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Introduction
Freescale Semiconductor, Inc.
•
Maximum Operating Frequency:
185 MHz @ Vin = 500 mVpp, 4.5 V Minimum Supply
100 MHz @ Vin = 500 mVpp, 3.0 V Minimum Supply
•
Operating Supply Current:
0.6 mA @ 3.0 V, 30 MHz
1.5 mA @ 3.0 V, 100 MHz
3.0 mA @ 5.0 V, 50 MHz
5.8 mA @ 5.0 V, 185 MHz
•
Operating Temperature Range: -40 to 85°C
•
R Counter Division Range: 1 and 5 to 32,767
•
N Counter Division Range: 40 to 65,535
•
Direct Interface to Motorola SPI Serial Data Port
•
See Application Notes AN1207/D and AN1671/D
•
Contact Motorola for MC145170 control software.
Table 1. Comparision of the PLL Frequency Synthesizers
Parameter
Minimum Supply Voltage
Maximum Input Current, fin
Dynamic Characteristics, fin (Figure 26)
Power-On Reset Circuit
2
MC145170-2
MC145170-1
2.7 V
2.5 V
150 µA
120 µA
Unchanged
-
Improved
-
MC145170-2 Technical Data
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Freescale Semiconductor, Inc.
Electrical Characteristics
1
OSCin
OSCout
OSC
3
4-Stage
Reference
Divider
9
fR Control
15-stage R Counter
2
fR
15
REFout
3
BitGrabber R Register
15 Bits
11
Lock Detector and Control
LD
7
CLK
5
Din
8
Dout
Shift
Register
And Control
Logic
16
BitGrabber C Register
8 Bits
Phase/Frequency Detector A
and Control
13
PDout
Freescale Semiconductor, Inc...
POR
ENB
14
Phase/Frequency Detector B
and Control
6
15
BitGrabber N Register
16 Bits
16
10
fV Control
fin
4
Input
AMP
fR
fV
fV
Pin 16 = VDD
Pin 12 = VSS
16-Stage N Counter
This device contains 4,800 active transistors.
Figure 1. Block Diagram
2 Electrical Characteristics
Table 2. Maximum Ratings (Voltages Referenced to VSS)
Parameter
Symbol
Value
Unit
DC Supply Voltage
VDD
-0.5 to 5.5
V
DC Input Voltage
Vin
-0.5 to VDD + 0.5
V
DC Output Voltage
Vout
-0.5 to VDD + 0.5
V
DC Input Current, per Pin
Iin
±10
mA
DC Output Current, per Pin
Iout
±20
mA
DC Supply Current, VDD and VSS Pins
IDD
±30
mA
Power Dissipation, per Package
PD
300
mW
Storage Temperature
Tstg
-65 to 150
°C
TL
260
°C
Lead Temperature, 1 mm from Case
for 10 seconds
NOTES: 1. Maximum Ratings are those values beyond which damage to the device may occur.
Functional operation should be restricted to the limits in the Electrical Characteristics
tables or Pin Descriptions section.
2. ESD data available upon request.
MOTOROLA
MC145170-2 Technical Data
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3
Electrical Characteristics
Freescale Semiconductor, Inc.
Table 3. Electrical Characteristics
Parameter
(Voltages Referenced to VSS, TA = -40 to 85°C)
Test Condition
Power Supply Voltage Range
Maximum Low-Level Input
Voltage [Note 1]
(Din, CLK, ENB, fin)
dc Coupling to fin
Minimum High-Level Input
Voltage [Note 1]
(Din, CLK, ENB, fin)
dc Coupling to fin
Freescale Semiconductor, Inc...
Minimum Hysteresis Voltage
(CLK, ENB)
Symbol
VDD
V
Guaranteed
Limit
Unit
VDD
-
2.7 to 5.5
V
VIL
2.7
4.5
5.5
0.54
1.35
1.65
V
VIH
2.7
4.5
5.5
2.16
3.15
3.85
V
VHys
2.7
5.5
0.15
0.20
V
Maximum Low-Level Output
Voltage (Any Output)
Iout = 20 µA
VOL
2.7
5.5
0.1
0.1
V
Minimum High-Level Output
Voltage (Any Output)
Iout = - 20 µA
VOH
2.7
5.5
2.6
5.4
V
Minimum Low-Level Output
Current (PDout, REFout, fR, fV,
LD, φR, φV)
Vout = 0.3 V
Vout = 0.4 V
Vout = 0.5 V
IOL
2.7
4.5
5.5
0.12
0.36
0.36
mA
Minimum High-Level Output
Current (PDout, REFout, fR, fV,
LD, φR, φV)
Vout = 2.4 V
Vout = 4.1 V
Vout = 5.0 V
IOH
2.7
4.5
5.5
-0.12
-0.36
-0.36
mA
Minimum Low-Level Output
Current (Dout)
Vout = 0.4 V
IOL
4.5
1.6
mA
Minimum High-Level Output
Current (Dout)
Vout = 4.1 V
IOH
4.5
-1.6
mA
Maximum Input Leakage Current
(Din, CLK, ENB, OSCin)
Vin = VDD or VSS
Iin
5.5
±1.0
µA
Maximum Input Current
(fin)
Vin = VDD or VSS
Iin
5.5
±150
µA
Maximum Output Leakage
Current
(PDout)
(Dout)
Vin = VDD or VSS,
Output in High-Impedance
State
5.5
5.5
±100
±5.0
nA
µA
5.5
100
µA
Maximum Quiescent Supply
Current
Vin = VDD or VSS; Outputs
Open; Excluding fin Amp
Input Current Component
IOZ
IDD
NOTES: 1. When dc coupling to the OSCin pin is used, the pin must be driven rail-to-rail. In this case, OSC out should be floated.
2. The nominal values at 3.0 V are 0.6 mA @ 30 MHz, and 1.5 mA @ 100 MHz. The nominal values at 5.0 V are 3.0 mA @ 50 MHz,
and 5.8 mA @ 185 MHz. These are not guaranteed limits.
4
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Freescale Semiconductor, Inc.
Electrical Characteristics
Table 3. Electrical Characteristics (Continued) (Voltages Referenced to VSS, TA = -40 to 85°C)
Parameter
Test Condition
Freescale Semiconductor, Inc...
Maximum Operating Supply
Current
fin = 500 mVpp;
OSCin = 1.0 MHz @ 1.0
Vpp;
LD, fR, fV, REFout = Inactive
and No Connect; OSCout,
φV, φR, PDout = No Connect;
Din, ENB, CLK = VDD or
VSS
Symbol
VDD
V
Guaranteed
Limit
Unit
Idd
-
[Note 2]
mA
NOTES: 1. When dc coupling to the OSCin pin is used, the pin must be driven rail-to-rail. In this case, OSC out should be floated.
2. The nominal values at 3.0 V are 0.6 mA @ 30 MHz, and 1.5 mA @ 100 MHz. The nominal values at 5.0 V are 3.0 mA @ 50 MHz,
and 5.8 mA @ 185 MHz. These are not guaranteed limits.
Table 4. AC Interface Characteristics
( TA = -40 to 85°C, CL = 50 pF, Input tr = tf = 10 ns, unless otherwise noted.)
Parameter
Serial Data Clock Frequency (Note: Refer to Clock
tw Below)
Symbol
Figure
No.
VDD
V
Guaranteed
Limit
fclk
2
2.7
4.5
5.5
dc to 3.0
dc to 4.0
dc to 4.0
MHz
tPLH, tPHL
2, 6
2.7
4.5
5.5
150
85
85
ns
tPLZ, tPHZ
3, 7
2.7
4.5
5.5
300
200
200
ns
tPZL, tPZH
3, 7
2.7
4.5
5.5
0 to 200
0 to 100
0 to 100
ns
tTLH, tTHL
2, 6
2.7
4.5
5.5
150
50
50
ns
2, 6
2.7
4.5
5.5
900
150
150
ns
Maximum Propagation Delay, CLK to Dout
Maximum Disable Time, Dout Active to High
Impedance
Access Time, Dout High Impedance to Active
Maximum Output Transition Time, Dout
CL = 50 pF
CL = 200 pF
Unit
Maximum Input Capacitance - Din, ENB, CLK
Cin
-
10
pF
Maximum Output Capacitance - Dout
Cout
-
10
pF
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5
Electrical Characteristics
Freescale Semiconductor, Inc.
Table 5. Timing Requirements (TA = -40 to 85°C, Input tr = tf = 10 ns, unless otherwise noted.)
Parameter
Symbol
Figure
No.
VDD
V
Guaranteed
Limit
tsu, th
4
2.7
4.5
5.5
55
40
40
ns
tsu, th, trec
5
2.7
4.5
5.5
135
100
100
ns
tw(H)
5
2.7
4.5
5.5
400
300
300
ns
tw
2
2.7
4.5
5.5
166
125
125
ns
t r, t f
2
2.7
4.5
5.5
100
100
100
µs
Minimum Setup and Hold Times, Din vs CLK
Minimum Setup, Hold, and Recovery Times, ENB
vs CLK
Freescale Semiconductor, Inc...
Minimum Inactive-High Pulse Width, ENB
Minimum Pulse Width, CLK
Maximum Input Rise and Fall Times, CLK
6
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Unit
MOTOROLA
Freescale Semiconductor, Inc.
Electrical Characteristics
2.1 Switching Waveforms
tf
VDD
tr
VDD
90%
CLK 50%
10%
VSS
tPZL
VSS
tw
tw
Dout
1/fclk
tPLH
Dout
ENB
50%
tPHL
Dout
90%
High Impedance
Figure 3.
tw(H)
VDD
50%
ENB
th
VSS
tsu
th
VSS
CLK
Figure 4.
VSS
Last CLK
Figure 5.
Test Point
Test Point
7.5 kΩ
CL*
* Includes all probe and fixture capacitance.
Figure 6. Test Circuit
MOTOROLA
VDD
50%
First CLK
Device
Under
Test
trec
VDD
50%
CLK
VDD
50%
VSS
tsu
VSS
tTHL
Valid
Din
VDD
tPHZ
50%
Figure 2.
Freescale Semiconductor, Inc...
High Impedance
10%
tPZH
90%
50%
10%
tTLH
tPLZ
50%
Device
Under
Test
CL*
Connect to VDD
when testing tPLZ
AND tPZL. Connect
to VSS when testing
tPHZ and tPZH.
*Includes all probe and fixture capacitance.
Figure 7. Test Circuit
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7
Electrical Characteristics
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Table 6. Loop Specifications (TA = -40 to 85°C)
Freescale Semiconductor, Inc...
Parameter
Test Condition
Symbol
Figure
No.
VDD
V
Guaranteed Range
Unit
Min
Max
f
8
2.7
3.0
4.5
5.5
5.0
5.0
25
45
80
100
185
185
MHz
Input Frequency, fin
[Note}
Vin ≥ 500 mVpp Sine
Wave,
N Counter Set to
Divide Ratio
Such that fV ≤ 2.0 MHz
f
9
2.7
3.0
4.5
5.5
1.0*
1.0*
1.0*
1.0*
22
25
30
35
MHz
Input Frequency, OSCin
Externally Driven with
ac-coupled Signal
Vin ≥ 1.0 Vpp Sine
Wave,
OSCout = No Connect,
R Counter Set to
Divide Ratio Such that
fR ≤ 2 MHz
C1 ≤ 30 pF
C2 ≤ 30 pF
Includes Stray
Capacitance
fXTAL
11
2.7
3.0
4.5
5.5
2.0
2.0
2.0
2.0
12
12
15
15
MHz
Crystal Frequency,
OSCin and OSCout
Output Frequency,
REFout
fout
12, 14
2.7
4.5
5.5
dc
dc
dc
10
10
MHz
CL = 30 pF
2.7
4.5
5.5
dc
dc
dc
2.0
2.0
MHz
Operating Frequency of
the
Phase Detectors
f
Output Pulse Width, φR,
φV, and LD
fR in Phase with fV
CL = 50 pF
Output Transition Times,
φR, φV, LD, fR, and fV
CL = 50 pF
Input Capacitance fin
OSCin
tw
13, 14
2.7
4.5
5.5
20
16
100
90
ns
tTLH,
tTHL
13, 14
2.7
4.5
5.5
-
65
60
ns
Cin
-
-
-
7.0
7.0
pF
* IF lower frequency is desired, use wave shaping or higher amplitude sinusoidal signal in ac-coupled case. Also, see Figure 25 for dc coupling.
100 pF
Sine Wave
Generator
fin
Vin
fV
Test Point
MC145170-2
50 Ω*
VSS
VDD
V+
*Characteristic impedance
Figure 8. Test Circuit, fin
8
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Electrical Characteristics
0.01 µF
Sine Wave
Generator
V+
OSCin
Test Point
1.0 MΩ
5.0 MΩ
50 Ω
fR
MC145170-2
Vin
Sine Wave
Generator
OSCout
VSS
0.01 µF
OSCin
VDD
1.0 MΩ
Vin
V+
fR
MC145170-2
OSCout
50 Ω
VSS
VDD
V+
Freescale Semiconductor, Inc...
No Connect
Figure 9. Test Circuit, OSC Circuitry Externally
Driven [Note]
Test Point
Figure 10. Circuit to Eliminate Self-Oscillation,
OSC Circuitry Externally Driven [Note]
NOTE: Use the circuit of Figure 10 to eliminate self-oscillation of the OSCin pin when the MC145170-2 has power applied with no
external signal applied at Vin. (Self-oscillation is not harmful to the MC145170-2 and does not damage the IC.)
OSCin
C1
MC145170-2
REFout
C2
OSCout
VSS
1/f REFout
Test Point
REFout
VDD
50%
V+
Figure 11. Test Circuit, OSC Circuit with Crystal
Figure 12. Test Circuit
Test Point
Output
tw
Output
50%
Device
Under
Test
90%
10%
tTHL
CL*
tTLH
*Includes all probe and fixture capacitance.
Figure 13. Switching Waveform
MOTOROLA
Figure 14. Test Load Circuit
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Pin Connections
3 Pin Connections
3.1 Digital Interface Pins
Din
Serial Data Input (Pin 5)
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The bit stream begins with the most significant bit (MSB) and is shifted in on the low-to-high transition of
CLK. The bit pattern is 1 byte (8 bits) long to access the C or configuration register, 2 bytes (16 bits) to
access the N register, or 3 bytes (24 bits) to access the R register. Additionally, the R register can be
accessed with a 15-bit transfer (see Table 7). An optional pattern which resets the device is shown in
Figure 15. The values in the C, N, and R registers do not change during shifting because the transfer of
data to the registers is controlled by ENB.
The bit stream needs neither address nor steering bits due to the innovative BitGrabber registers.
Therefore, all bits in the stream are available to be data for the three registers. Random access of any
register is provided (i.e., the registers may be accessed in any sequence). Data is retained in the registers
over a supply range of 2.7 to 5.5 V. The formats are shown in Figures 15, 16, 17, and 18.
Din typically switches near 50% of VDD to maximize noise immunity. This input can be directly interfaced
to CMOS devices with outputs guaranteed to switch near rail-to-rail. When interfacing to NMOS or TTL
devices, either a level shifter (MC74HC14A, MC14504B) or pull-up resistor of 1 to 10 kΩ must be used.
Parameters to consider when sizing the resistor are worst-case IOL of the driving device, maximum
tolerable power consumption, and maximum data rate.
Table 7. Register Access
(MSBs are shifted in first, C0, N0, and R0 are the LSBs)
Number
of Clocks
Accessed
Register
Bit
Nomenclature
9 to 13
8
16
15 or 24
Other Values ≤ 32
Values > 32
See Figure 15
C Register
N Register
R Register
None
See Figures 27 to 34
(Reset)
C7, C6, C5, ..., C0
N15, N14, N13, ..., N0
R14, R13, R12, ..., R0
CLK
Serial Data Clock Input (Pin 7)
Low-to-high transitions on Clock shift bits available at Din, while high-to-low transitions shift bits from
Dout. The chip's 16-1/2-stage shift register is static, allowing clock rates down to dc in a continuous or
intermittent mode.
Four to eight clock cycles followed by five clock cycles are needed to reset the device; this is optional.
Eight clock cycles are required to access the C register. Sixteen clock cycles are needed for the N register.
Either 15 or 24 cycles can be used to access the R register (see Table 7 and Figures 15, 16, 17, and 18). For
cascaded devices, see Figures 27 to 34.
CLK typically switches near 50% of VDD and has a Schmitt-triggered input buffer. Slow CLK rise and fall
times are allowed. See the last paragraph of Din for more information.
NOTE: To guarantee proper operation of the power-on reset (POR) circuit, the CLK pin must be held at
the potential of either the VSS or VDD pin during power up. That is, the CLK input should not be floated or
toggled while the VDD pin is ramping from 0 to at least 2.7 V. If control of the CLK pin is not practical
during power up, the initialization sequence shown in Figure 15 must be used.
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Pin Connections
ENB
Active-Low Enable Input (Pin 6)
This pin is used to activate the serial interface to allow the transfer of data to/from the device. When ENB
is in an inactive high state, shifting is inhibited, Dout is forced to the high-impedance state, and the port is
held in the initialized state. To transfer data to the device, ENB (which must start inactive high) is taken
low, a serial transfer is made via Din and CLK, and ENB is taken back high. The low-to-high transition on
ENB transfers data to the C, N, or R register depending on the data stream length per Table 7.
NOTE: Transitions on ENB must not be attempted while CLK is high. This puts the device out of
synchronization with the microcontroller. Resynchronization occurs when ENB is high and CLK is low.
This input is also Schmitt-triggered and switches near 50% of VDD, thereby minimizing the chance of
loading erroneous data into the registers. See the last paragraph of Din for more information.
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Dout
Three-State Serial Data Output (Pin 8)
Data is transferred out of the 16-1/2-stage shift register through Dout on the high-to-low transition of CLK.
This output is a No Connect, unless used in one of the manners discussed below.
Dout could be fed back to an MCU/MPU to perform a wrap-around test of serial data. This could be part of
a system check conducted at power up to test the integrity of the system's processor, PC board traces,
solder joints, etc.
The pin could be monitored at an in-line QA test during board manufacturing.
Finally, Dout facilitates troubleshooting a system and permits cascading devices.
3.2 Reference Pins
OSCin /OSCout
Reference Oscillator Input/Output (Pins 1, 2)
These pins form a reference oscillator when connected to terminals of an external parallel-resonant crystal.
Frequency-setting capacitors of appropriate values as recommended by the crystal supplier are connected
from each pin to ground (up to a maximum of 30 pF each, including stray capacitance). An external
feedback resistor of 1.0 to 5.0 MΩ is connected directly across the pins to ensure linear operation of the
amplifier. The required connections for the components are shown in Figure 11.
5 MΩ is required across the OSCin and OSCout pins in the ac-coupled case (see Figure 9 or alternate circuit
Figure 10). OSCout is an internal node on the device and should not be used to drive any loads (i.e.,
OSCout is unbuffered). However, the buffered REFout is available to drive external loads.
The external signal level must be at least 1 Vpp; the maximum frequencies are given in the Loop
Specifications table. These maximum frequencies apply for R Counter divide ratios as indicated in the
table. For very small ratios, the maximum frequency is limited to the divide ratio times 2 MHz. (Reason:
the phase/frequency detectors are limited to a maximum input frequency of 2 MHz.)
If an external source is available which swings virtually rail-to-rail (VDD to VSS), then dc coupling can be
used. In the dc-coupled case, no external feedback resistor is needed. OSCout must be a No Connect to
avoid loading an internal node on the device, as noted above. For frequencies below 1 MHz, dc coupling
must be used. The R counter is a static counter and may be operated down to dc. However, wave shaping
by a CMOS buffer may be required to ensure fast rise and fall times into the OSCin pin. See Figure 25.
Each rising edge on the OSCin pin causes the R counter to decrement by one.
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Pin Connections
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REFout
Reference Frequency Output (Pin 3)
This output is the buffered output of the crystal-generated reference frequency or externally provided
reference source. This output may be enabled, disabled, or scaled via bits in the C register (see Figure 16).
REFout can be used to drive a microprocessor clock input, thereby saving a crystal. Upon power up, the onchip power-on-initialize circuit forces REFout to the OSCin divided-by-8 mode.
REFout is capable of operation to 10 MHz; see the Loop Specifications table. Therefore, divide values for
the reference divider are restricted to two or higher for OSCin frequencies above 10 MHz.
If unused, the pin should be floated and should be disabled via the C register to minimize dynamic power
consumption and electromagnetic interference (EMI).
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3.3 Counter Output Pins
fR
R Counter Output (Pin 9)
This signal is the buffered output of the 15-stage R counter. fR can be enabled or disabled via the C register
(patented). The output is disabled (static low logic level) upon power up. If unused, the output should be
left disabled and unconnected to minimize interference with external circuitry.
The fR signal can be used to verify the R counter's divide ratio. This ratio extends from 5 to 32,767 and is
determined by the binary value loaded into the R register. Also, direct access to the phase detector via the
OSCin pin is allowed by choosing a divide value of 1 (see Figure 17). The maximum frequency which the
phase detectors operate is 2 MHz. Therefore, the frequency of fR must not exceed 2 MHz.
When activated, the fR signal appears as normally low and pulses high. The pulse width is 4.5 cycles of the
OSCin pin signal, except when a divide ratio of 1 is selected. When 1 is selected, the OSCin signal is
buffered and appears at the fR pin.
fV
N Counter Output (Pin 10)
This signal is the buffered output of the 16-stage N counter. fV can be enabled or disabled via the C register
(patented). The output is disabled (static low logic level) upon power up. If unused, the output should be
left disabled and unconnected to minimize interference with external circuitry.
The fV signal can be used to verify the N counter's divide ratio. This ratio extends from 40 to 65,535 and is
determined by the binary value loaded into the N register. The maximum frequency which the phase
detectors operate is 2 MHz. Therefore, the frequency of fV must not exceed 2 MHz.
When activated, the fV signal appears as normally low and pulses high.
3.4 Loop Pins
fin
Frequency Input (Pin 4)
This pin is a frequency input from the VCO. This pin feeds the on-chip amplifier which drives the N
counter. This signal is normally sourced from an external voltage-controlled oscillator (VCO), and is accoupled into fin. A 100 pF coupling capacitor is used for measurement purposes and is the minimum size
recommended for applications (see Figure 25). The frequency capability of this input is dependent on the
supply voltage as listed in Table 6, Loop Specifications. For small divide ratios, the maximum frequency is
limited to the divide ratio times 2 MHz. (Reason: the phase/frequency detectors are limited to a maximum
frequency of 2 MHz.)
12
MC145170-2 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc.
Pin Connections
For signals which swing from at least the VIL to VIH levels listed in the Electrical Characteristics table,
dc coupling may be used. Also, for low frequency signals (less than the minimum frequencies shown in the
Loop Specifications table), dc coupling is a requirement. The N counter is a static counter and may be
operated down to dc. However, wave shaping by a CMOS buffer may be required to ensure fast rise and
fall times into the fin pin. See Figure 25.
Each rising edge on the fin pin causes the N counter to decrement by 1.
PDout
Single-Ended Phase/Frequency Detector Output (Pin 13)
This is a three-state output for use as a loop error signal when combined with an external low-pass filter.
Through use of a Motorola patented technique, the detector's dead zone has been eliminated. Therefore, the
phase/frequency detector is characterized by a linear transfer function. The operation of the phase/
frequency detector is described below and is shown in Figure 19.
Freescale Semiconductor, Inc...
POL bit (C7) in the C register = low (see Figure 16)
Frequency of fV > fR or Phase of fV Leading fR: negative pulses from high impedance
Frequency of fV < fR or Phase of fV Lagging fR: positive pulses from high impedance
Frequency and Phase of fV = fR: essentially high-impedance state; voltage at pin determined by loop filter
POL bit (C7) = high
Frequency of fV > fR or Phase of fV Leading fR: positive pulses from high impedance
Frequency of fV < fR or Phase of fV Lagging fR: negative pulses from high impedance
Frequency and Phase of fV = fR: essentially high-impedance state; voltage at pin determined by loop filter
This output can be enabled, disabled, and inverted via the C register. If desired, PDout can be forced to the
high-impedance state by utilization of the disable feature in the C register (patented).
φR and φV
Double-Ended Phase/Frequency Detector Outputs
(Pins 14, 15)
These outputs can be combined externally to generate a loop error signal. Through use of a Motorola
patented technique, the detector's dead zone has been eliminated. Therefore, the phase/frequency detector
is characterized by a linear transfer function. The operation of the phase/frequency detector is described
below and is shown in Figure 19.
POL bit (C7) in the C register = low (see Figure 16)
Frequency of fV > fR or Phase of fV Leading fR: φV = negative pulses, φR = essentially high
Frequency of fV < fR or Phase of fV Lagging fR: φV = essentially high, φR = negative pulses
Frequency and Phase of fV = fR: φV and φR remain essentially high, except for a small minimum time
period when both pulse low in phase
POL bit (C7) = high
Frequency of fV > fR or Phase of fV Leading fR: φR = negative pulses, φV = essentially high
Frequency of fV < fR or Phase of fV Lagging fR: φR = essentially high, φV = negative pulses
Frequency and Phase of fV = fR: φV and φR remain essentially high, except for a small minimum time
period when both pulse low in phase
These outputs can be enabled, disabled, and interchanged via the C register (patented).
MOTOROLA
MC145170-2 Technical Data
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13
Freescale Semiconductor, Inc.
Pin Connections
LD
Lock Detector Output (Pin 11)
This output is essentially at a high level with narrow low-going pulses when the loop is locked (fR and fV
of the same phase and frequency). The output pulses low when fV and fR are out of phase or different
frequencies (see Figure 19).
This output can be enabled and disabled via the C register (patented). Upon power up, on-chip
initialization circuitry disables LD to a static low logic level to prevent a false “lock” signal. If unused, LD
should be disabled and left open.
3.5 Power Supply
Freescale Semiconductor, Inc...
VDD
Most Positive Supply Potential (Pin 16)
This pin may range from 2.7 to 5.5 V with respect to VSS.
For optimum performance, VDD should be bypassed to VSS using low-inductance capacitor(s) mounted
very close to the device. Lead lengths on the capacitor(s) should be minimized. (The very fast switching
speed of the device causes current spikes on the power leads.)
VSS
Most Negative Supply Potential (Pin 12)
This pin is usually ground. For measurement purposes, the VSS pin is tied to a ground plane.
Power Up
ENB
CLK
1
2
3
1
2
3
4
5
One
Zero
4 or More Clocks
Din
Don't Cares
Zeroes
Don't Cares
NOTE: This initialization sequence is usually not necessary because the on-chip power-on reset circuit performs the
initialization function. However, this initialization sequence must be used immediately after power up if control of the
CLK pin is not possible. That is, if CLK (Pin 7) toggles or floats upon power up, use the above sequence to reset the
device. Also, use this sequence if power is momentarily interrupted such that the supply voltage to the device is
reduced to below 2.7 V, but not down to at least 1 V (for example, the supply drops down to 2 V). This is necessary
because the on-chip power-on reset is only activated when the supply ramps up from a voltage below
approximately 1.0 V.
Figure 15. Reset Sequence
14
MC145170-2 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc.
Pin Connections
ENB
1
CLK
2
3
4
5
6
7
MSB
Din
C7
8
*
LSB
C6
C5
C4
C3
C2
C1
C0
* At this point, the new byte is transferred to the C register and stored. No other registers are affected.
Freescale Semiconductor, Inc...
C7 - POL:
Select the output polarity of the phase/frequency detectors. When set high, this
bit inverts PDout and interchanges the φR function with φV as depicted in
Figure 19. Also see the phase detector output pin descriptions for more
information. This bit is cleared low at power up.
C6 - PDA/B: Selects which phase/frequency detector is to be used. When set high, enables the
output of phase/frequency detector A (PDout) and disables phase/frequency
detector B by forcing φR and φV to the static high state. When cleared low,
phase/frequency detector B is enabled (φR and φV) and phase/frequency detector
A is disabled with PDout forced to the high-impedance state. This bit is cleared
low at power up.
C5 - LDE:
Enables the lock detector output when set high. When the bit is cleared low, the
LD output is forced to a static low level. This bit is cleared low at power up.
C4 - C2, OSC2 - OSC0:
Reference output controls which determines the REFout characteristics as shown
below. Upon power up, the bits are initialized such that OSCin/8 is selected.
REFout Frequency
C4
C3
C2
0
0
0
dc (Static Low)
0
0
1
OSCin
0
1
0
OSCin /2
0
1
1
OSCin /4
1
0
0
OSCin /8 (POR
Default)
1
0
1
OSCin /16
1
1
0
OSCin /8
1
1
1
OSCin /16
C1 - fVE:
Enables the fV output when set high. When cleared low, the fV output is forced to
a static low level. The bit is cleared low upon power up.
C0 - fRE:
Enables the fR output when set high. When cleared low, the fR output is forced to
a static low level. The bit is cleared low upon power up.
Figure 16. C Register Access and Format (8 Clock Cycles are Used)
MOTOROLA
MC145170-2 Technical Data
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15
16
n
LK
NB
X
MSB
1
X
2
Din
CLK
ENB
X
3
MC145170-2 Technical Data
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X
R11
4
X
R10
9
5
R13
11
6
R8
12
R7
R12
7
See Below
R9
R14
10
8
R6
R11
13
9
R9
R5
10
R4
15
See Below
R10
14
11
R8
R3
16
12
R7
R2
17
R5
19
13
R1
14
See Below
R6
18
Octal Value
0
0
0
0
0
0
0
0
.
.
.
F
F
0
0
0
0
0
0
0
0
.
.
.
7
7
0
0
0
0
0
0
0
0
.
.
.
F
F
0
1
2
3
4
5
6
7
.
.
.
E
F
Hexadecimal Value
R12
R13
15
R4
R Counter = ÷32,766
R Counter = ÷32,767
Decimal Equivalent
Not Allowed
R Counter = ÷1 (Direct Access to Reference Side of Phase/Frequency Detector)
Not Allowed
Not Allowed
Not Allowed
R Counter = ÷5
R Counter = ÷6
R Counter = ÷7
R0
3
X
8
R14
2
X
7
LSB
6
MSB
1
Don't Care Bits
X
5
* At this point, the new data is transferred to the R register and stored. No other registers are affected.
X
4
Freescale Semiconductor, Inc...
20
R3
21
R1
23
See Below
R2
22
R0
LSB
24
Pin Connections
Freescale Semiconductor, Inc.
*
*
Figure 17. R Register Access and Formats (Either 24 or 15 Clock Cycles Can Be Used)
MOTOROLA
Freescale Semiconductor, Inc.
Pin Connections
ENB
CLK
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
MSB
N15
Freescale Semiconductor, Inc...
Din
*
LSB
N14
N13
N12
N11
N10
N9
0
0
0
0
.
.
.
0
0
0
0
0
0
0.
.
.
F
F
N8
0
0
0
0
.
.
.
0
0
0
0
0
0
0.
.
.
F
F
N7
0
0
0
0
.
.
.
2
2
2
2
2
2
2.
.
.
F
F
0
1
2
3
.
.
.
5
6
7
8
9
A
B.
.
.
E
F
Hexadecimal Value
N6
N5
N4
N3
N2
N1
N0
Not Allowed
Not Allowed
Not Allowed
Not Allowed
Not Allowed
Not Allowed
Not Allowed
N Counter = ÷40
N Counter = ÷41
N Counter = ÷42
N Counter = ÷43
N Counter = ÷65,534
N Counter = ÷65,535
Decimal Equivalent
*At this point, the two new bytes are transferred to the N register and stored. No other registers are affected. In addition, the N
and R counters are jam-loaded and begin counting down together.
Figure 18. N Register Access and Format (16 Clock Cycles Are Used)
fR
Reference
OSCin ÷ R
VH
fV
Feedback
(fin ÷ N
VH
VL
VL
*
PDout
VH
High Impedance
VL
VH
VL
φR
VH
φV
VL
VH
LD
VL
VH = High voltage level
VL = Low voltage level
*At this point, when both fR and fV are in phase, both the sinking and sourcing output FETs are turned on for a very short internal.
NOTE: The PDout generates error pulses during out-of-lock conditions. When locked in phase and frequency, the output is high
impedance and the voltage at that pin is determined by the low-pass filter capacitor. PDout, φR and φV are shown with the polarity bit
(POL) = low; see Figure 16 for POL.
Figure 19. Phase/Frequency Detector and Lock Detector Output Waveforms
MOTOROLA
MC145170-2 Technical Data
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17
Design Considerations
Freescale Semiconductor, Inc.
4 Design Considerations
4.1 Crystal Oscillator Considerations
The following options may be considered to provide a reference frequency to Motorola's CMOS frequency
synthesizers.
4.1.1 Use of a Hybrid Crystal Oscillator
Freescale Semiconductor, Inc...
Commercially available temperature-compensated crystal oscillators (TCXOs) or crystal-controlled data
clock oscillators provide very stable reference frequencies. An oscillator capable of CMOS logic levels at
the output may be direct or dc coupled to OSCin. If the oscillator does not have CMOS logic levels on the
outputs, capacitive or ac coupling to OSCin may be used (see Figures 9 and 10).
For additional information about TCXOs, visit motorola.com on the world wide web.
4.1.2 Use of the On-Chip Oscillator Circuitry
The on-chip amplifier (a digital inverter) along with an appropriate crystal may be used to provide a
reference source frequency. A fundamental mode crystal, parallel resonant at the desired operating
frequency, should be connected as shown in Figure 20.
The crystal should be specified for a loading capacitance (CL) which does not exceed 20 pF when used
at the highest operating frequencies listed in Table 6, Loop Specifications. Larger CL values are possible
for lower frequencies. Assuming R1 = 0 Ω, the shunt load capacitance (CL) presented across the crystal
can be estimated to be:
C C
in out
C1 ¥ C2
C L = ----------------------------- + C a + C stray + ---------------------C in + C out
C1 + C2
where
Cin = 5.0 pF (see Figure 21)
Cout = 6.0 pF (see Figure 21)
Ca = 1.0 pF (see Figure 21)
C1 and C2 = external capacitors (see Figure 21)
Cstray = the total equivalent external circuit stray
capacitance appearing across the crystal
terminals
The oscillator can be “trimmed” on-frequency by making a portion or all of C1 variable. The crystal and
associated components must be located as close as possible to the OSCin and OSCout pins to minimize
distortion, stray capacitance, stray inductance, and startup stabilization time. Circuit stray capacitance can
also be handled by adding the appropriate stray value to the values for Cin and Cout. For this approach, the
term Cstray becomes 0 in the above expression for CL.
A good design practice is to pick a small value for C1, such as 5 to 10 pF. Next, C2 is calculated. C1 < C2
results in a more robust circuit for start-up and is more tolerant of crystal parameter variations.
Power is dissipated in the effective series resistance of the crystal, Re, in Figure 22. The maximum drive
level specified by the crystal manufacturer represents the maximum stress that the crystal can withstand
without damage or excessive shift in operating frequency. R1 in Figure 20. limits the drive level. The use
of R1 is not necessary in most cases.
18
MC145170-2 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc. Design Considerations
To verify that the maximum dc supply voltage does not cause the crystal to be overdriven, monitor the
output frequency at the REFout pin (OSCout is not used because loading impacts the oscillator). The
frequency should increase very slightly as the dc supply voltage is increased. An overdriven crystal
decreases in frequency or becomes unstable with an increase in supply voltage. The operating supply
voltage must be reduced or R1 must be increased in value if the overdriven condition exists. The user
should note that the oscillator start-up time is proportional to the value of R1.
Through the process of supplying crystals for use with CMOS inverters, many crystal manufacturers have
developed expertise in CMOS oscillator design with crystals. Discussions with such manufacturers can
prove very helpful (see Table 8).
Frequency
Synthesizer
Freescale Semiconductor, Inc...
OSCin
OSCout
Rf
R1*
C1
5.0 to 10 pF
C2
* May be needed in certain cases. See text.
Figure 20. Pierce Crystal Oscillator Circuit
Ca
OSCout
OSCin
Cin
Cout
Cstray
Figure 21. Parasitic Capacitances of the Amplifier and Cstray
1
2
CS
LS
RS
1
2
CO
1
Re
Xe
2
NOTE: Values are supplied by crystal manufacturer (parallel resonant crystal).
Figure 22. Equivalent Crystal Networks
MOTOROLA
MC145170-2 Technical Data
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19
Design Considerations
Freescale Semiconductor, Inc.
Recommended Reading
Technical Note TN-24, Statek Corp.
Technical Note TN-7, Statek Corp.
E. Hafner, “The Piezoelectric Crystal Unit-Definitions and Method of Measurement”, Proc. IEEE, Vol.
57, No. 2, Feb. 1969.
D. Kemper, L. Rosine, “Quartz Crystals for Frequency Control”, Electro-Technology, June 1969.
P. J. Ottowitz, “A Guide to Crystal Selection”, Electronic Design, May 1966.
D. Babin, “Designing Crystal Oscillators”, Machine Design, March 7, 1985.
D. Babin, “Guidelines for Crystal Oscillator Design”, Machine Design, April 25, 1985.
Contact Motorola for MC145170-2 control software.
Freescale Semiconductor, Inc...
Table 8. Partial List of Crystal Manufacturers
CTS Corp.
United States Crystal Corp.
Crystek Crystal
Statek Corp.
Fox Electronics
NOTE:
20
Motorola cannot recommend one
supplier over another and in no
way suggests that this is a
complete listing of crystal
manufacturers.
MC145170-2 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc. Design Considerations
(A)
PDout
K K
φ VCO
------------------------NR C
1
Nω
n
ζ = -----------------------------2K K
φ VCO
VCO
ω
R1
C
n
=
1
F ( s ) = -------------------------R sC + 1
1
(B)
PDout
VCO
ω
R1
n
=
R2


N
ζ = 0.5 ω  R C + -------------------------
n 2
K K
φ VCO
C
Freescale Semiconductor, Inc...
K K
φ VCO
-----------------------------------NC ( R + R )
1
2
R 2 sC + 1
F ( s ) = --------------------------------------------( R 1 + R 2 ) sC + 1
(C)
R2
φR
φV
R1
R1
R2
n
=
C
+
ω
A
VCO
MC33077 or
equivalent
(Note 3)
C
K K
φ VCO
------------------------NCR
1
ω n R2 C
ζ = -------------------2
R sC + 1
2
F ( s ) = -------------------------R sC
1
Notes:
1. For (C), R1 is frequently split into two series resistors; each resistor is equal to R1 divided
by 2. A capacitor CC is then placed from the midpoint to ground to further filter the error
pulses. The value of CC should be such that the corner frequency of this network does not
significantly affect ωn.
2. The φR and φV outputs swing rail-to-rail. Therefore, the user should be careful not to
exceed the common mode input range of the op amp.
3. For the latest information on MC33077 or equivalent, see the Motorola IC web site at
http://www.motorola.com/semiconductors.
Denifitions:
N = Total Division Ratio in Feedback Loop
Kφ (Phase Detector Gain) = VDD/4p volts per radian for PDout
Kφ (Phase Detector Gain) - VDD/2p volts per radian for fV and fR
2π∆fVCO
K VCO ( VCO Gain ) = ------------------------∆V VCO
For a nominal design starting point, the user might consider a damping factor ζ = 0.7 and a natural loop
frequency ωn = (2πfR/50) where fR is the frequency at the phase detector input. Larger ωn values result
in faster loop lock times and, for similar sideband filtering, higher fR-related VCO standards.
Figure 23. Phase-Locked Loop - Low Pass Filter Design
MOTOROLA
MC145170-2 Technical Data
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21
Design Considerations
Freescale Semiconductor, Inc.
VHF Output
Buffer
VHF VCO
Low-pass Filter
V+
VDD 16
2 OSC
out
φV 15
3 REF
φR 14
4
5
6
7
Freescale Semiconductor, Inc...
MCU
fin
Din
MC145170-2
V+
1 OSC
in
PDout
Threshold
Detector
Optional
(Note 5)
13
VSS 12
ENB
LD 11
CLK
fV 10
8 D
out
Optional
Optional
Loop Error Signals
(Note 1)
fR 9
Integrator
(Note 4)
NOTES:
1. The φR and φV outputs are fed to an external combiner/loop filter. See the Phase-Locked Loop — Low-Pass
Filter Design page for additional information. The φR and φV outputs swing rail-to-rail. Therefore, the user
should be careful not to exceed the common mode input range of the op amp used inthe combiner/loop filter.
2. For optimum performance, bypass the VDD pin to VSS (GND) with one or more low-inductance capacitors.
3. The R counter is programmed for a divide value = OSCin/fR. Typically, fR is the tuning resolution required for
the VCO. Also, the VCO frequency divided by fR = N, wher e N is the divide value of the N counter.
4. May be an R-C low-pass filter.
5. May be a bipolar transistor.
Figure 24. Example Application
22
MC145170-2 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc. Design Considerations
V+
VDD
14
A
1
2
C
OSCin
MC74HC14A
B
3
Freescale Semiconductor, Inc...
No Connect
MC145170-2
4
7
OSCout
D
fin
VSS
NOTE:
The signals at Points A and B may be low-frequency sinusoidal or square
waves with slow edge rates or noisy signal edges. At Points C and D, the
signals are cleaned up, have sharp edge rates, and rail-to-rail signal swings.
With signals as described at Points C and D, the MC145170-2 is guaranteed to
operate down to a frequency as low as dc.
Refer to the MC74HC14A data sheet for input switching levels and hysteresis
voltage range.
Figure 25. Low Frequency Operation Using DC Coupling
MOTOROLA
MC145170-2 Technical Data
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23
Design Considerations
Freescale Semiconductor, Inc.
f(Pin
4)
in
SOG Package
1
2
3
Freescale Semiconductor, Inc...
4
Marker
Frequency
(MHz)
Resistance
(Ω)
Reactance
(Ω)
Capacitance
(pF)
1
2
3
4
5
100
150
185
2390
39.2
25.8
42.6
-5900
-347
-237
-180
5.39
4.58
4.48
4.79
Figure 26. Input Impedance at fin - Series Format (R + jX)
(5.0 MHz to 185 MHz)
Device #1
MC145170-2
Din
CLK
ENB
Device #2
MC145170-2
Dout
Din
CLK
ENB
Dout
33 kΩ
NOTE 1
CMOS
MCU
Optional
NOTES:
1. The 33 kΩ resistor is needed to prevent the Din pin from floating. (The Dout pin is a three-state output.)
2. See related Figures 28, 29, and 30.
Figure 27. Cascading Two MC145170-2 Devices
24
MC145170-2 Technical Data
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MOTOROLA
25
X
1
X
2
7
X
8
X
9
X
10
15
X
16
C6
18
23
24
C0
C Register Bits of Device #2
in Figure 27
C7
17
X
25
X
26
MC145170-2 Technical Data
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X
1
X
2
8
X
9
X
10
25
R14
26
R13
30
R9
31
R Register Bits of Device #2
in Figure 27
27
R1
39
R0
40
X
41
R14
42
44
X
32
48
R7
49
50
R6
R Register Bits of Device #1
in Figure 27
R11
45
C6
34
39
55
40
C0
C Register Bits of Device #1
in Figure 27
33
C7
Figure 29. Accessing the R Registers of Two Cascaded MC145170-2 Devices
NOTE: At this point, the new data is transferred to the R registers of both devices and stored. No other registers are affected.
Din
CLK
ENB
31
Figure 28. Accessing the C Registers of Two Cascaded MC145170-2 Devices
NOTE: At this point, the new data is transferred to the C registers of both devices and stored. No other registers are affected.
Din
CLK
ENB
Freescale Semiconductor, Inc...
R0
56
NOTE
NOTE
Freescale Semiconductor, Inc.
MOTOROLA
26
X
1
X
2
8
X
9
X
10
15
X
16
N15
17
N8
24
N7
25
N Register Bits of Device #2
in Figure 27
23
31
N0
32
N15
33
N8
40
N7
41
N Register Bits of Device #1
in Figure 27
39
Figure 30. Accessing the N Registers of Two Cascaded MC145170-2 Devices
NOTE: At this point, the new data is transferred to the N registers of both devices and stored. No other registers are affected.
Din
CLK
ENB
Freescale Semiconductor, Inc...
47
N0
48
NOTE
Freescale Semiconductor, Inc.
MC145170-2 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc. Design Considerations
V+
VPD
VDD
VDD
Device #1
MC145170-2
Din
CLK
ENB
VCC
VPD
Device #2
Note 2
Dout
Din
CLK
ENB
Output A
(Dout)
33 kΩ
Note 1
CMOS
MCU
Freescale Semiconductor, Inc...
Optional
NOTES:
1. The 33 kΩ resistor is needed to prevent the Din pin from floating. (The Dout pin is a three-state output.)
2. This PLL Frequency Synthesizer may be a MC145190, MC145191, MC145192, MC145200, or MC145201.
3. See related Figures 32, 33, and 34.
Figure 31. Cascading Two Different Device Types
MOTOROLA
MC145170-2 Technical Data
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27
28
X
1
X
2
7
X
8
X
9
X
10
15
X
16
C6
18
23
24
C0
C Register Bits of Device #2
in Figure 31
C7
17
X
25
X
26
MC145170-2 Technical Data
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X
1
X
2
16
A23
17
X
32
A22
18
20
A18
22
30
31
A9
A Register Bits of Device #2
in Figure 31
A19
21
A8
32
39
A0
40
X
41
R14
42
R13
43
R9
47
R8
48
R Register Bits of Device #1
in Figure 31
46
C6
34
Figure 33. Accessing the A and R Registers of Two Different Device Types
39
55
C Register Bits of Device #1
in Figure 31
C7
33
NOTE: At this point, the new data is transferred to the A register of Device #2 and R register of Device #1 and stored. No other registers are affected.
Din
CLK
ENB
31
Figure 32. Accessing the C Registers of Two Different Device Types
NOTE: At this point, the new data is transferred to the C registers of both devices and stored. No other registers are affected.
Din
CLK
ENB
Freescale Semiconductor, Inc...
C0
40
R0
56
NOTE
NOTE
Freescale Semiconductor, Inc.
MOTOROLA
29
X
1
X
2
8
X
9
X
10
15
X
16
R15
17
R8
24
R7
25
R Register Bits of Device #2
in Figure 31
23
31
R0
32
N15
33
N8
40
N7
41
N Register Bits of Device #1
in Figure 31
39
Figure 34. Accessing the R and N Registers of Two Different Device Types
NOTE: At this point, the new data is transferred to the R register of Device #2 and N register of Device #1 and stored. No other registers are affected.
Din
CLK
ENB
Freescale Semiconductor, Inc...
47
N0
48
NOTE
Freescale Semiconductor, Inc.
MC145170-2 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc.
Packaging
5 Packaging
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME
Y14.5M, 1994.
2. CONTROLLING DIMENSION: INCH.
3. DIMENSION L TO CENTER OF LEADS WHEN
FORMED PARALLEL.
4. DIMENSION B DOES NOT INCLUDE MOLD FLASH.
5. ROUNDED CORNERS OPTIONAL.
-A16
9
1
8
B
F
C
L
S
-T-
SEATING
PLANE
K
H
Freescale Semiconductor, Inc...
D
M
J
G
16 PL
0.25 (0.010) M T A
M
DIM
A
B
C
D
F
G
H
J
K
L
M
S
INCHES
MIN
MAX
0.740 0.770
0.250 0.270
0.145 0.175
0.015 0.021
0.040
0.70
0.100 BSC
0.050 BSC
0.008 0.015
0.110 0.130
0.295 0.305
0_
10_
0.020 0.040
MILLIMETERS
MIN
MAX
18.80 19.55
6.35
6.85
3.69
4.44
0.39
0.53
1.02
1.77
2.54 BSC
1.27 BSC
0.21
0.38
2.80
3.30
7.50
7.74
0_
10_
0.51
1.01
Figure 35. Outline Dimensions for P Suffix, DIP-16
(Case 648-08, Issue R)
0.25
8X
PIN'S
NUMBER
M
B
1
1.75
1.35
A
6.2
5.8
0.25
0.10
16X
16
0.49
0.35
0.25
T A B
14X
PIN 1 INDEX
1.27
4
A
8
NOTES:
1. DIMENSIONS ARE IN MILLIMETERS.
2. DIMENSIONING AND TOLERANCING PER ASME
Y14.5M, 1994.
3. DATUMS A AND B TO BE DETERMINED AT THE PLANE
WHERE THE BOTTOM OF THE LEADS EXIT THE PLASTIC
BODY.
4. THIS DIMENSION DOES NOT INCLUDE MOLD FLASH,
PROTRUSION OR GATE BURRS, MOLD FLASH,
PROTRUSIONS OR GATE BURRS SHALL NOT EXCEED
0.15 MM PER SIDE. THIS DIMENSION IS DETERMINED AT
THE PLANE WHERE THE BOTTOM OF THE LEADS EXIT
THE PLASTIC BODY.
5. THIS DIMENSION DOES NOT INCLUDE INTER-LEAD FLASH
OR PROTRUSIONS. INTER-LEAD FLASH AND
PROTRUSIONS SHALL NOT EXCEED 0.25 MM PER SIDE.
THIS DIMENSION IS DETERMINED AT THE PLANE WHERE
THE BOTTOM OF THE LEADS EXIT THE PLASTIC BODY.
6. THIS DIMENSION DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR PROTRUSION SHALL
NOT CAUSE THE LEAD WIDTH TO EXCEED 0.62 MM.
10.0
9.8
A
9
T
4.0
3.8
SEATING
PLANE
16X
B
0.1 T
5
0.50
0.25
6
M
X45°
0.25
0.19
1.25
0.40
7°
0°
SECTION A-A
Figure 36. Outline Dimensions for D Suffix, SOG-16
(Case 751B-05, Issue J)
30
MC145170-2 Technical Data
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MOTOROLA
Freescale Semiconductor, Inc.
A
-P-
16x
K
REF
0.200 (0.008)
16
M
T
9
B
L
PIN 1
IDENTIFICATION
Freescale Semiconductor, Inc...
1
8
0.100 (0.004)
-T-
M
NOTES:
1. DIMENSIONING AND TOLERANCING PER ASME
Y14.5M, 1994.
2. CONTROLLING DIMENSION: MILLIMETER.
3. DIMENSION A DOES NOT INCLUDE MOLD FLASH,
PROTRUSIONS OR GATE BURRS. MOLD FLASH
OR GATE BURRS SHALL NOT EXCEED 0.15
(0.006) PER SIDE.
4. DIMENSION B DOES NOT INCLUDE INTERLEAD
FLASH OR PROTRUSION SHALL NOT EXCEED
0.25 (0.010) PER SIDE.
5. DIMENSION K DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR
PROTRUSION SHALL BE 0.08 (0.003) TOTAL
EXCESS OF THE K DIMENSION AT MAXIMUM
MATERIAL CONDITION.
6. TERMINAL NUMBERS ARE SHOWN FOR
REFERENCE ONLY.
7. DIMENSIONS A AND B ARE TO BE DETERMINED
AT DATUM PLANE -U-.
-U-
C
D
H
G
SEATING
PLANE
A
K
K1
J1
Packaging
DIM
A
B
C
D
F
G
H
J
J1
K
K1
L
M
MILLIMETERS
MIN
MAX
--5.10
4.30
4.50
--1.20
0.05
0.25
0.45
0.55
0.65 BSC
0.22
0.23
0.09
0.24
0.09
0.18
0.16
0.32
0.16
0.26
6.30
6.50
05
105
INCHES
MIN
MAX
--- 0.200
0.169 0.177
--0047
0.002 0.010
0.018 0.022
0.026 BSC
0.009 0.010
0.004 0.009
0.004 0.007
0.006 0.013
0.006 0.010
0.248 0.256
05
105
M
J
A
SECTION A-A
F
Figure 37. Outline Dimensions for DT Suffix, TSSOP-16
(Case 948C-03, Issue B)
MOTOROLA
MC145170-2 Technical Data
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31
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Freescale Semiconductor, Inc.
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MC145170-2/D
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