LANSDALE ML145146-6P 4-bit data bus input pll frequency synthesizer Datasheet

ML145146
4–Bit Data Bus Input PLL
Frequency Synthesizer
INTERFACES WITH DUAL–MODULUS PRESCALERS
Legacy Device: Motorola MC145146-2
The ML145146 is programmed by a 4–bit input, with
strobe and address lines. The device features consist of a
reference oscillator, 12–bit programmable reference
divider, digital phase detector, 10–bit programmable
divide–by–N counter, 7–bit divide–by–A counter, and the
necessary latch circuitry for accepting the 4–bit input data.
20
1
1
CROSS REFERENCE/ORDERING INFORMATION
PACKAGE
MOTOROLA
LANSDALE
P DIP 20
MC145146P2
ML145146RP
SOG 20W
MC145146DW2 ML145146-6P
Note: Lansdale lead free (Pb) product, as it
becomes available, will be identified by a part
number prefix change from ML to MLE.
PIN ASSIGNMENT
BLOCK DIAGRAM
12–BIT ÷ R COUNTER
OSCout
D0
D1
D2
D3
A2
A1
A0
ST
L5
LATCH
CONTROL
CIRCUITRY
fR
LOCK
DETECT
L7
PHASE
DETECTOR A
LATCHES
L2
fin
L6
L3
LD
D1
1
20
D2
D0
2
19
D3
fin
3
18
fR
VSS
4
17
φR
PDout
5
16
φV
VDD
6
15
fV
OSCin
7
14
MC
OSCout
8
13
LD
A0
9
12
ST
A1
10
11
A2
PDout
fV
L4
10–BIT ÷ N COUNTER
L0
L1
PHASE
DETECTOR B
φV
φR
7–BIT ÷ A COUNTER
MODULUS CONTROL (MC)
CONTROL LOGIC
Page 1 of 12
SOG 20 W = -6P
SOG PACKAGE
CASE 751D
20
• Operating Temperature Range: TA – 40 to +85°C
• Low Power Consumption Through the Use of
CMOS Technology
• 3.0 to 9.0 V Supply Range
• Programmable Reference Divider for Values Between
3 and 4095
• Dual–Modulus 4–Bit Data Bus Programming
• ÷ N Range = 3 to 1023, ÷ A Range= 0 to 127
• “Linearized” Digital Phase Detector Enhances
Transfer Function Linearity
• Two Error Signal Options:
Single–Ended (Three–State)
Double–Ended
OSCin
P DIP 20 = RP
PLASTIC DIP
CASE 738
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ML145146
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PIN DESCRIPTIONS
INPUT PINS
D0 - D3
Data Inputs (Pins 2, 1, 20, 19)
Information at these inputs is transferred to the internal
latches when the ST input is in the high state. D3 (Pin 19) is
the most significant bit.
f in
Frequency Input (Pin 3)
Input to ÷N portion of synthesizer f in is typically derived
from loop VCO and is AC coupled into Pin 3. For larger
amplitude signals (standard CMOS – logic levels) DC coupling
may be used.
OSCin/OSCout
Reference Oscillator Input/Output (Pins 7 and 8)
These pins form an on–chip reference oscillator when connected to terminals of an external parallel resonant crystal.
Frequency setting capacitors of appropriate value must be connected from OSCin to ground and OSCout to ground. OSCin
may also serve as input for an externally–generated reference
signal. This signal is typically AC coupled to OSCin, but for
larger amplitude signals (standard CMOS–logic levels) DC
coupling may also be used. In the external reference mode, no
connection is required to OSCout.
A0 - A2
Address Inputs (Pins 9, 10, 11)
A0, A1 and A2 are used to define which latch receives the
information on the data input lines. The addresses refer to the
following latches.
A2
A1
A0
Selected
Function
D0
D1
D2
0
0
0
Latch 0
÷ A Bits
0
1
2
D3
3
0
0
1
Latch 1
÷ A Bits
4
5
6
—
0
1
0
Latch 2
÷ N Bits
0
1
2
3
0
1
1
Latch 3
÷ N Bits
4
5
5
7
1
0
0
Latch 4
÷ N Bits
8
9
—
—
1
0
1
Latch 5
Reference Bits
0
1
2
3
1
1
0
Latch 6
Reference Bits
4
5
6
7
1
1
1
Latch 7
Reference Bits
8
9
10
11
ST
Strobe Transfer (Pin 12)
The rising edge of strobe transfers data into the addressed
latch. The falling edge of strobe latches data into the latch.
This pin should normally be held low to avoid loading latches
with invalid data.
OUTPUT PINS
PDout
Single–ended Phase Detector Output (Pin 5)
Three–state output of phase detector for use as loop error
signal.
Frequency fV>fR or fV Leading: Negative Pulses
Frequency fV<fR or fV Lagging: Negative Pulses
Frequency fV=fR and Phase Coincidence: High–Impedance
State
Page 6 of 12
LD
Lock Detector (Pin 13)
High level when loop is locked (fR, fV of same phase and
frequency). Pulses low when loop is out of lock.
MC
Modulus Control (Pin 14)
Signal generated by the on–chip control logic circuitry for
controlling an external dual–modulus prescaler. The modulus
control level is low at beginning of a count cycle and remains
low until the ÷A counter has counted down from its programmed value. At this time, modulus control goes high and
remains high until the ÷N counter has counted the rest of the
way down from its programmed value (N – A additional counter since both ÷N and ÷A are counting down during the first
portion of the cycle). Modulus control is then set back low, the
counters preset to their respective programmed values, and the
above sequence repeated. This provides for a total programmable divide value (NT) = N • P ÷ A where P and P ÷ 1 represent
the dual–modulus prescaler divide values respectively for high
and low modulus control levels. N the number programmed
into the ÷N counter and A the number programmed into the
÷A counter.
fV
÷N Counter Output (Pin 15)
This pin is the output of the ÷N counter that is internallly
connected to the phase detector input. With this output available, the ÷N counter can be used independently.
φV, φR
Phase Detector Outpiuts (Pins 16 adn 17)
These phase detector outputs can be combined externally for
a loop error signal. A single–ended output is also available for
this purpose (see PDout).
If frequency fV is greater than fR or if the phase of fV is
leading, then error information is provided by φV pulsing low
φR remains essentially high.
If the frequency fV is less than fR or if the phase of fV is
lagging, then error information is provided by φR pulsing low
φV remains essentially high.
If the frequency of fV = fR and both are in phase, then both
φV and φR remain high except for a small minimum time period when both pulse low in phase.
fR
÷R Counter Output (Pin 18)
This is the output of the ÷ R counter that is internally connected to the phase detector input. With this output available,
the ÷ R counter can be used independently.
POWER SUPPLY PINS
VSS
Ground (Pin 4)
Circuit Ground
VDD
Positive Power Supply (Pin 6)
The positive supply voltage may range from 3.0 to 9.0 V
with respect to VSS.
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DESIGN CONSIDERATIONS
CRYSTAL OSCILLATOR CONSIDERATIONS
The following options may be considered to provide a reference frequency to Motorola’s CMOS frequency synthesizers.
The most desirable is discussed first.
Use of a Hybrid Crystal Oscillator
Commercially available temperature–compensated crystal
oscillators (TCXOs) or crystal–controlled data clock oscillators provide very stable reference frequencies. An oscillator
capable of sinking and sourcing 50 µA at CMOS logic levels
may be direct or DC coupled to OSCin. In general, the highest
frequency capability is obtained utilizing a direct coupled
square wave having a rail–to–rail (VDD to VSS) voltage
swing. If the oscillator does not have CMOS logic levels on the
outputs, capacitive or AC coupling of OSCin may be used.
OSCout, an unbuffered output, should be left floating.
For additional information about TCXOs and data clock
oscillators, please consult the latest version of the eem
Electronic Engineers Master Catalog, the Gold Book, or similar publications.
Design an Off–Chip Reference
The user may design and off–chip crystal oscillator using
ICs specifically developed for crystal oscillator applications,
such as the ML12061 MECL device. The reference signal from
the MECL device is AC coupled to OSCin. For large amplitude signals (standard CMOS logic levels), DC coupling is
used. OSCout, an unbuffered output, should be left floating. In
general, the highest frequency capability is obtained with a
direct–coupled square wave having rail–to–rail voltage swing.
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 8.
For VDD = 5.0 V, the crystal should be specified for a loading capacitance. CL, which does not exceed 32 pF for frequencies to approximately 8.0 MHz, 20 pF for frequencies in the
area of 8.0 to 15 MHz, and 10 pF for higher frequencies. These
are guidelines that provide a reasonable compromise between
IC capacitance, drive capability, swamping variations stray in
IC input/output capacitance, and realistic CL values. The shunt
load capacitance, CL, presented across the crystal can be estimated to be:
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. In some cases, stray
capacitance should be added to the value for Cin and Cout.
Power is dissipated in the effective series resistance of the
crystal, Re. In Figure 10 The drive level specified by the crystal manufacturer is the maximum stress that a crystal can withstand without damaging or excessive shift in frequency. R1 in
Figure 8 limits the drive level. The use of R1 may not be necessary in some cases (i.e. R1 = 0 ohms).
To verify that the maximum DC supply voltage does not
overdrive the crystal, monitor the output frequency as a function of voltage at OSCout. (care should be taken to minimize
loading.) the frequency should increase very slightly as the dc
supply voltage is increased. An overdriven crystal will decrease
in frequency or become unstable with an increase in supply
voltage. The operating supply voltage must be reduced or R1
must be increased in value if the overdrive 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 1.
where
Cin = 5.0pF (See Figure 9)
Cout = 6.0pF (See Figure 9)
Ca = 1.0pF (See Figure 9)
CO = the crystal’s holder capacitance (See Figure 10)
C1 and C2 = external capacitors (See Figure 8)
Page 8 of 12
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ML145146
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–Tecchnology, June 1969
P.J. Ottowitz, “AGuide to Crystal Selection”, Electronic
Design, May 1966
DUAL–MODULUS PRESCALING
The technique of dual–modulus prescaling is well established as a method of acheiving high performance frequency
synthesizer operation at high frequencies. Basically, the
approach allows relatively low–frequency programmable counters to be used as high–frequency programmable counters with
speed capability of several hundred MHz. This is possible
without the sacrifice in system resolution and performance that
results if a fixed (single–modulus) divider is used for the
prescaler.
In dual–modulus prescaling, the lower speed counters must
be uniquely configured. Special control logic is necessary to
select the divide value P or P ÷ 1 in the prescaler for the
required amount of time (see modullus control definition).
Lansdale’s dual–modulus frequency synthesizers contain this
feature and can be used with a variety of dual–modulus
prescalers to allow speed, complexity and cost to be tailored to
the system requirements. Prescalers having P, P ÷ 1 divide values in the range of ÷3/÷4 to ÷128/÷129 can be controlled by
most Lansdale frequency synthesizers.
Several dual–modulus prescaler approaches suitable for use
with the ML145146 are:
ML12009
ML12011
ML12013
ML12015
ML12016
ML12017
ML12018
ML12032
÷5/÷6
÷8/÷9
÷10/÷11
÷32/÷33
÷40/÷41
÷64/÷65
÷128/÷129
÷64/65 or ÷128/129
440 MHz
500 MHz
500 MHz
225 MHz
225 MHz
225 MHz
520 MHz
1.1 GHz
DESIGN GUIDELINES
The system total divide value. Ntotal (NT) will be dictated
by the application. i.e.,
Page 9 of 12
N is the number programmed into the ÷N counter, A is the
number programmed into the ÷A counter, P and P ÷ 1 are the
two selectable divide ratios available in the dual–modulus
prescalers. To have a range of NT values in sequence, the ÷A
counter is programmed from zero through P ÷ 1 for a particular value N in the ÷N counter. N is then incremented to the N
÷ 1, and the ÷A is sequenced from 0 through P ÷ 1 again.
There are minimum and maximum values that can be
achieved for NT. These values are a function of P and the size
of the ÷N and ÷A counters. The constraint N ≥ A always
applies. If Amax = P – 1, then Nmin ≥ P – 1. Then NTmin =
(P – 1) P + A or (P – 1)P since A is free to assume the value of 0.
NTmax ÷ Nmax • P + Amax
To maximize system frequency capability, the dual–modulus
prescaler output must go from low to high after each group of
P or P – 1 input cycles. The prescaler should divide by P when
its modulus control line is high and by P – 1 when the modulus
control is low.
For the maximum frequency into the prescaler (fVCOmax),
the value used for P must be large enough such that:
1. fVCO max divided by P may not exceed the frequency
capability of f in (input to the ÷N and ÷A counters).
2. The period of fVCO divided by P must be greater than the
sum of the times:
a. Propagation delay through the dual modulus
prescaler.
b. Prescaler setup or release time relative to its modulus
control signal.
c. Propagation time from f in to the modulus control
output for the frequency synthesizer device.
A sometimes useful simplification in the programming code
can be achieved by choosing the values for P of 8, 16, 32, or
64. For these cases, the desired value of NT results when NT
in binary is used as the program code to the ÷N and ÷A counters treated in the following manner:
1. Assume the ÷A counter contains “a” bits where 2a≥P.
2. Always program all higher order ÷A counter bits
above “a” to 0
3. Assume the ÷N counter and the ÷A counter (with all
the higher order bits above “a” ignored) combined
into a single binary counter of n + a bits in length (n =
number of divider stages in the ÷N counter). The
MSB of this “hypothetical” counter is to correspond to
the MSB of ÷N and the LSB is to correspond to the
LSB of ÷A. The system divide value, NT, now results
when the value of NT in binary is used to program
the “new” n + a bit counter.
By using the two devices, several dual–modulus values are
achievable (shown in Figure 11).
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ML145146
APPLICATION
MC
The features of the ML145146 permit bus operation with a
dedicated wire needed only for the strobe input. In a microprocessor–controlled system this strobe input is accessed
when the phase lock loop is addressed. The remaining data
and address inputs will directly interface to the microprocessor’s data and address buses.
The device architecture allows the user to establish any
integer reference divide value between 3 and 4095. The wide
selection of ÷R values permits a high degree of flexibility in
choosing the reference oscillator frequency. As a result the
reference oscillator can frequently be chosen to serve multiple system functions such as a second local oscillator in a
receiver design or a microprocessor system clock. Typical
applications that take advantage of these ML145146 features
including the dual modulus capability are shown in Figures
12, 13 and 14.
Page 10 of 12
DEVICE A
DEVICE A
DEVICE
B
DEVICE B
ML12009
ML12011
MC10131
÷20/÷21
÷32/÷33
ML12013
÷40/÷41
MC10138
÷50/÷51
÷80/÷81
÷100/÷101
÷40/÷41
OR
÷80/÷81
÷64/÷65
OR
÷128/÷129
÷80/÷81
MC10154
NOTE: ML12009, ML12011 and ML12013 are pin equivalent.
ML12015, ML12016 and ML12017 are pin equivalent.
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Figure 11. Dual Modulus Values
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LANSDALE Semiconductor, Inc.
ML145146
CHOICE OF
REF. OSC.
FREQUENCY
(ON–CHIP OSC.
OPTIONAL)
}
FOR USE WITH EXTERNAL
PHASE DETECTOR (OPTIONAL)
7
6
4
18
fR
8
OSCout
15
fV
13
LD
OSCin
ML145146
VDD
LOCK DETECT
SIGNAL
PDout 5
φR 17
φV 16
}
MOD 14
CONTROL
VSS
3
fin
D3 D2 D1 D0 A2 A1 A0
ST
19 20 1
2
11 10 9
12
TO SHARED CONTROLLER BUS
RECEIVER LO.
443.325 443.950 MHz
(25 kHz STEPS)
LOOP
FILTER
TRANSMITTER
MODULATION
AND 15.7 MHz TRANSMITTER SIGNAL
OFFSET
459.025 – 459.650 MHz
(25 kHz STEPS)
VCO
CHOICE OF DETECTOR
ERROR SIGNALS
ML12034 PRESCALER
CHIP
SELECT TO
CONTROLLER
NOTES:
1. Reciever I.F = 10.7 MHz, low side injection.
2. Duplex operation with 5 MHz receive/transmit separation.
3. fR = 25 kHz, + R chosen to correspond with desired reference oscillator frequency.
4. Ntotal = 17,733 to 17,758 = N • P + A; N = 227, A = 5 to 30 for P = 64.
Figure 13. Synthesizer for UHF Mobil Radio Telephone Channels Demonstrates Use of the ML145146 in
Microprocessor/Microcomputer Controlled Systems Operating to Several Hundred MHz
CHOICE OF
REF. OSC.
FREQUENCY
(ON–CHIP OSC.
OPTIONAL)
7
6
}
FOR USE WITH EXTERNAL
PHASE DETECTOR (OPTIONAL)
X3
8
OSCout
fR
OSCin
VDD
fV
LOCK DETECT
SIGNAL
5
LD
RECEIVER FIRST L.O.
825.030 844.980 MHZ
(30 KHz STEPS)
PDout
φR 17
ML145146
RECEIVER
2ND, L.O.
33,300 MHZ
φV 16
MOD 14
CONTROL
4
VSS
fin 3
D3 D2 D1 D0 A2 A1 A0
ST
19 20 1
2
11 10 9
12
CHIP
TO SHARED CONTROLLER BUS SELECT TO
CONTROLLER
}
LOOP
FILTER
VCO
X4
TRANSMITTER
MODULATION
CHOICE OF DETECTOR
ERROR SIGNALS
X4
TRANSMITTER SIGNAL
825.030 844.880 MHz
(30 kHz STEPS)
MC10131
DUAL F/F
ML12011
÷8/÷9 PRESCALER
+32/+32 DUAL MODULUS PRESCALER
NOTES:
1. Receiver 1st I.F. = 45 MHz, low side injection; Receiver 2nd I.F. = 11.7 MHz, low side injection.
2. Duplex operation with 45 MHz receive/transmit separation.
3. fR = 7.5 kHz, + R = 1480.
4. Ntotal = N • 32 + A = 27,501 to 28,166: N = 859 to 880; A = 0 to 31.
5. Only one implementation is shown. Various other configurations and dual–modulus prescaling values to ÷128/÷129 are possible.
Figure 14. 666 Channel, Computer Controlled, Mobile Radio Telephone Synthesizer for
800 MHz Cellular Radio Systems
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ML145146
OUTLINE DIMENSIONS
SOG = -6P
(MC145146-6P)
CASE 751D-04
-A20
NOTES:
1. DIMENSIONING AND TOLERANCING PER ANSI
Y14.5M, 1982
2. CONTROLLING DIMENSION: MILLIMETER
3. DIMENSIONA AND B DO NOT INCLUDE
MOLD PROTRUSION.
4. MAXIMUM MOLD PROTRUSION 0.150 (0.006)
PER SIDE
5. DIMENSION D DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR
PROTRUSION SHALL BE 0.13 (0.005) TOTAL, IN
EXCESS OF D DIMENSION AT MAXIMUM
MATERIAL CONDITION.
11
-B-
1
1
P 10 PL
0.25 (0.010)
M
B
M
0
J
0.25 (0.010) M T B
S
A
S
DIM
A
B
C
D
F
G
J
K
M
P
R
F
R X 45°
C
-T-
INCHES
MIN
MAX
12.65
12.95
7.40
7.60
2.35
2.65
0.35
0.49
0.50
0.90
1.27 BSC
0.25
0.32
0.10
0.25
MILLIMETERS
MIN
MAX
0.499
0.510
0.292
0.299
0.093
0.104
0.014
0.019
0.020
0.035
0.050 BSC
0.010
0.012
0.020
0.035
10.05
0.25
.0395
0.010
10.56
0.75
0.415
0.029
M
K
PLASTIC DIP
(MC145146RP)
CASE 738-03
-A20
NOTES:
1. DIMENSIONING AND TOLERANCING PER ANSI
Y14.5M, 1982
2. CONTROLLING DIMENSION: INCH
3. DIMENSION L TO CENTER OF LEAD WHEN
FORMED PARALLEL
4. DIMENSION B DOES NOT INCLUDE MOLD
FLASH
11
B
1
1
0
C
-T-
L
K
SEATING
PLANE
M
E
G
N
F
D 20 PL
0.25 (0.010) M T A
J 20 PL
0.25 (0.010) M T B
M
M
DIM
A
B
C
D
E
F
G
J
K
L
M
N
INCHES
MIN
MAX
1.010
1.070
0.240
.0260
0.150
0.180
0.015
0.022
0.050 BSC
0.050
0.070
0.100 BSC
0.008
0.015
0.110
0.140
0.300 BSC
MILLIMETERS
MIN
MAX
25.66
27.17
6.10
6.60
3.81
4.57
0.39
0.55
1.27BSC
1.27
1.77
2.54 BSC
0.21
0.38
2.80
3.55
7.62 BSC
0.020
0.51
0.040
1.01
Lansdale Semiconductor reserves the right to make changes without further notice to any products herein to improve reliability, function or design. Lansdale does not assume any liability arising out of the application or use of any product or circuit
described herein; neither does it convey any license under its patent rights nor the rights of others. “Typical” parameters which
may be provided in Lansdale data sheets and/or specifications can vary in different applications, and actual performance may
vary over time. All operating parameters, including “Typicals” must be validated for each customer application by the customer’s
technical experts. Lansdale Semiconductor is a registered trademark of Lansdale Semiconductor, Inc.
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