SANYO LC72191

Ordering number : EN 3985C
CMOS LSI
LC72191, 72191M, 72191JM
PLL Frequency Synthesizer
for Electronic Tuning in Car Stereo Tuners
Overview
Package Dimensions
The LC72191, LC72191M and LC72191JM are PLL
frequency synthesizers for electronic tuning. The
LC72191, LC72191M and LC72191JM are optimal for
AM/FM tuner circuits that require high mounting
densities.
unit: mm
3067-DIP24S
[LC72191]
Features
Designed for use in car stereos, the LC72191 provides a
rich set of reference frequencies, I/O ports, a generalpurpose counter, and an unlock detection circuit.
Functions
• Programmable dividers
— FMIN pin: 130 MHz at 70 mVrms and 160 MHz at
100 mVrms input (built-in prescaler)
— AMIN pin: Pulse swallower and direct division
techniques
• Reference frequencies: Ten selectable frequencies:
1, 5, 9, 10, 3.125, 6.25, 12.5 25, 50 and 100 kHz
• Output ports: 7 pins
Complementary outputs: 2 pins
N-channel open drain outputs: 5 pins
• Input ports: 2 pins
• General-purpose counter: For measuring IF and other
signals (Also used for station detection when
functioning as an IF counter.)
— HCTR pin: Frequency measurement (for inputs up to
70 MHz)
— LCTR pin: Frequency and period measurement
• PLL unlock detection circuit
Detects phase differences of 0.55, 1.11, 2.22 and 3.33 µs.
• Controller clock output: 400 kHz
• Clock time base output: 8 Hz
• Serial data I/O
— Supports CCB format communication with the
system controller.
• Package: LC72191: DIP24S
LC72191M: MFP24
LC72191JM: MFP24S
SANYO: DIP24S
• CCB is a trademark of SANYO ELECTRIC CO., LTD.
• CCB is SANYO’s original bus format and all the bus
addresses are controlled by SANYO.
SANYO Electric Co.,Ltd. Semiconductor Bussiness Headquarters
TOKYO OFFICE Tokyo Bldg., 1-10, 1 Chome, Ueno, Taito-ku, TOKYO, 110 JAPAN
D3096HA (OT)/D2593JN/6182JN No. 3985-1/16
LC72191, 72191M, 72191JM
Package Dimensions
unit: mm
unit: mm
3045B-MFP24
3112-MFP24S
[LC72191M]
[LC72191JM]
SANYO: MFP24
SANYO: MFP24S
Pin Assignments
No. 3985-2/16
LC72191, 72191M, 72191JM
Block Diagram
Pin Symbols
XIN, XOUT:
FMIN, AMIN:
CE, CL, DI, DO:
OUT0 to OUT6:
IN0, IN1:
HCTR, LCTR:
PD1, PD2:
SYC:
Crystal oscillator (7.2 MHz)
Local oscillator signal input
Serial data I/O
Output ports
Input ports
General-purpose counter inputs
Charge pump outputs
Control clock (400 kHz)
Specifications
Absolute Maximum Ratings at Ta = 25°C, VSS = 0 V
Parameter
Maximum supply voltage
Input voltage
Output voltage
Symbol
VDD max
Conditions
Unit
–0.3 to +7.0
VIN (1)
CE, CL, DI, IN0, IN1
–0.3 to +7.0
V
VIN (2)
Input pins other than VIN (1)
–0.3 to VDD + 0.3
V
VOUT (1)
DO, SYC
VOUT (2)
OUT1, OUT2
VOUT (3)
OUT3 to OUT6, OUT0
VOUT (4)
Output pins other than VOUT (1), VOUT (2) and VOUT (3)
Ta ≤ 85°C
Allowable power dissipation
Ratings
VDD
Pd max
:LC72191
V
–0.3 to +7.0
V
–0.3 to VDD + 0.3
V
–0.3 to +15
V
–0.3 to VDD + 0.3
V
350
:LC72191M
300
:LC72191JM
200
mW
Operating temperature
Topr
–40 to +85
°C
Storage temperature
Tstg
–55 to +125
°C
No. 3985-3/16
LC72191, 72191M, 72191JM
Allowable Operating Ranges at Ta = –40 to +85°C, VSS = 0 V
Parameter
Supply voltage
Input high level voltage
Input low level voltage
Output voltage
Input frequency
Crystal oscillators for which
operation is guaranteed
Symbol
min
typ
max
Unit
VDD
4.5
6.5
V
VDD (2)
VDD: Crystal oscillator guaranteed operation
3.5
6.5
V
VIH (1)
CE, CL, DI, IN0, IN1
2.2
6.5
V
VIH (2)
LCTR: Pulse waveform, DC coupling*4
0.7 VDD (1)
VDD (1)
V
VIL (1)
CE, CL, DI, IN0, IN1
0
0.7
V
VIL (2)
LCTR*4
0
0.3 VDD (1)
V
VOUT (1)
DO, SYC
6.5
V
VOUT (2)
OUT3 to OUT6, OUT0
13
V
fIN (1)
XIN: Sine wave capacitor coupling, VDD (2)
1.0
fIN (2)
FMIN: Sine wave capacitor coupling, VDD (1)*1
10
fIN (3)
AMIN: Sine wave capacitor coupling, VDD (1)*1
0.5
40
MHz
fIN (4)
HCTR: Sine wave capacitor coupling, VDD (1)*2
10
60 (70)*6
MHz
fIN (5)
LCTR: Sine wave capacitor coupling, VDD (1)*3
15
500
kHz
fIN (6)
LCTR: Pulse wave DC coupling, VDD (1)*4
1.0
20 × 103
Hz
XIN, XOUT: CI ≤ 50 Ω
3.0
Xtal
VIN (1)
Input amplitude
Conditions
VDD (1)
XIN: Sine wave capacitor coupling, VDD (1)
MHz
MHz
8.0
MHz
1.5
Vrms
1.5
Vrms
VIN (2)
FMIN: Sine wave capacitor coupling, VDD (1)
VIN (3)
AMIN: Sine wave capacitor coupling, VDD (1)
VIN (5)
7.2
8.0
130 (160)*5
0.5
0.070
(0.100)*5
VIN (4)
7.2
0.070
1.5
Vrms
HCTR: Sine wave capacitor coupling, VDD
(1)*2
0.070
(0.100)*6
1.5
Vrms
LCTR: Sine wave capacitor coupling, VDD
(1)*3
0.070
1.5
Vrms
Note: 1.
2.
3.
4.
5.
6.
DV
SP
1/2 divider
1/16, 17 swallow
12-bit main divider
Input pin
1
*
10 to 130 (160) MHz
Input frequency
●
0
1
2 to 40 MHz
—
●
●
AMIN
0
0
0.5 to 10 MHz
—
—
●
●
●
FMIN
AMIN
DV and SP are bits in the serial data.
*: don’t care
Frequency measurement
Frequency measurement
Period measurement
fIN (2): 10 to 160 MHz/VIN (2)
0.100 Vrms (minimum)
fIN (4): 10 to 70 MHz/VIN (4)
0.100 Vrms (minimum)
No. 3985-4/16
LC72191, 72191M, 72191JM
Electrical Characteristics for the Allowable Operating Ranges
Parameter
Internal feedback resistance
Hysteresis
Input high level current
Input low level current
Output high level voltage
Output low level voltage
Output off leakage current
Symbol
Conditions
min
typ
max
Unit
Rf (1)
XIN
1.0
MΩ
Rf (2)
FMIN
500
kΩ
Rf (3)
AMIN
500
kΩ
Rf (4)
HCTR
500
kΩ
Rf (5)
LCTR
500
VH
LCTR
0.1 VDD
kΩ
0.6 VDD
V
IIH (1)
CE, CL, DI: VI = 6.5 V
5.0
µA
IIH (2)
IN0, IN1: VI = VDD
5.0
µA
IIH (3)
XIN: VI = VDD
20
µA
IIH (4)
FMIN, AMIN: VI = VDD
40
µA
IIH (5)
HCTR, LCTR: VI = VDD
40
µA
IIL (1)
CE, CL, DI: VI = VSS
5.0
µA
IIL (2)
IN0, IN1: VI = VSS
5.0
µA
IIL (3)
XIN: VI = VSS
20
µA
IIL (4)
FMIN, AMIN: VI = VSS
40
µA
IIL (5)
HCTR, LCTR: VI = VSS
40
µA
VOH (1)
OUT1, OUT2: IO = 1 mA
VDD – 1.0
VOH (2)
PD1, PD2: IO = 0.5 mA
VDD – 1.0
VOL (1)
OUT1, OUT2: IO = 1 mA
1.0
V
VOL (2)
PD1, PD2: IO = 0.5 mA
1.0
V
VOL (3)
OUT3 to OUT6: IO = 5 mA
1.0
V
VOL (4)
OUT0: IO = 1 mA
1.0
V
V
V
V
VOL (5)
DO: IO = 5 mA
1.0
VOL (6)
SYC: IO = 0.5 mA (VDD = 3.5 to 6.5 V)
1.0
V
IOFF (1)
OUT3 to OUT6, OUT0: VO = 13 V
5.0
µA
IOFF (2)
DO: VO = 6.5 V
5.0
µA
IOFF (3)
SYC: VO = 6.5 V (VDD = 3.5 to 6.5 V)
5.0
µA
Three-state high level
off leakage current
IOFFH
PD1, PD2: VO = VDD
0.01
10.0
nA
Three-state low level
off leakage current
IOFFL
PD1, PD2: VO = VSS
0.01
10.0
nA
Input capacitance
CIN
2
3
pF
IDD (1)
VDD: fIN (2) = 130 MHz, VIN (2) = 70 mVrms,
with a 7.2 MHz crystal, other input pins at VSS,
output pins open
20
30
mA
IDD (2)
VDD: PLL block stopped (PLL inhibit state), crystal
oscillator operating (SYC, TB), with a 7.2 MHz crystal,
other input pins at VSS, output pins open
1.0
Current drain
FMIN, HCTR
1
mA
Note: A capacitor of at least 2000 pF must be inserted between the power supply VDD and VSS potentials.
No. 3985-5/16
LC72191, 72191M, 72191JM
Pin Functions
Pin No.
Symbol
I/O
1
24
XIN
XOUT
Input
Output
19
FMIN
Input
Type
Function
Xtal OSC
• Connections for a 7.2 MHz crystal oscillator
Local oscillator signal
input
• FMIN is selected when DV in the serial input data is set to 1.
• Input frequency range: 10 to 130 MHz (70 mVrms minimum)
• The signal passes through an internal divide-by-two prescaler and is then supplied to
the swallow counter.
• Although the divisor setting is in the range 256 to 65,536, the actual divisor will be twice
the set value due to the presence of the internal divide-by-two prescaler.
18
AMIN
Input
Local oscillator signal
input
• AMIN is selected when DV in the serial input data is set to 0.
• When SP in the serial input data is set to 1:
— Input frequency range: 2 to 40 MHz (70 mVrms minimum).
— The signal is supplied directly to the swallow counter without passing through the
internal divide-by-two prescaler.
— The divisor setting is in the range 256 to 65,536 and the actual divisor will be the
value set.
• When SP in the serial input data is set to 0:
— Input frequency range: 0.5 to 10 MHz (70 mVrms minimum).
— The signal is supplied directly to a 12-bit programmable divider.
— The divisor setting is in the range 4 to 4,096 and the actual divisor will be the
value set.
21
22
PD1
PD2
Three-state
Charge pump outputs
• PLL charge pump outputs. High levels are output from PD1 and PD2 when the local
oscillator frequency divided by n is higher than the reference frequency, and low levels
are output when that frequency is lower than the reference frequency.
These pins go to the floating state when the frequencies agree.
6
SYC
N-channel
open drain
Controller clock
• SYC is a controller clock source. The LC72191 outputs a 400 kHz 66% duty signal
from this pin after power is applied.
20
VDD
—
Power supply
• The LC72191 power supply pin. A voltage of between 4.5 and 6.5 V must be provided
when the PLL is operating. The supply voltage can be lowered to 3.5 V when only
operating the crystal oscillator circuit to acquire the controller clock and the clock time
base outputs.
23
VSS
—
Ground
• The LC72191 ground pin
2
CE
Input*1
Chip enable
• This pin must be set high when inputting serial data (via DI) or when outputting serial
data (via DO).
4
CL
Input*1
Clock
• The clock input used for data signal synchronization during serial data input (via DI) or
output (via DO).
3
DI
Input*1
Input data
• Input pin used when transferring serial data from the controller to the LC72191.
• A total of 36 bits of data must be supplied to set up the LC72191 initial state.
5
DO
Output
(N-channel
open drain)
Output data
• Output pin used when transferring serial data to the controller from the LC72191.
• A total of 28 bits from an internal shift register can be output in synchronization with the
CL signal.
9
10
11
12
13
14
17
OUT0
OUT1
OUT2
OUT3
OUT4
OUT5
OUT6
Output port
• These pins latch bits O0 to O6 in the serial data transferred from the controller, invert
that data and output the inverted data in parallel.
• The OUT0 pin can also be used to output an 8 Hz clock time base signal.
(When TB is 1.)
• OUT1 and OUT2 are complementary outputs.
• OUT0, OUT3, OUT4, OUT5 and OUT6 are N-channel open drain outputs that can
handle up to 13 V.
Output*2
Note: *1. The high and low level input voltages for the CE, CL, DI, IN0 and IN1 pins are VIH = 2.2 to 6.5 V and VIL = 0 to 0.7 V, regardless of the power
supply voltage VDD.
*2. Since the output port states are undefined when power is first applied, transfer the control data quickly.
Continued on next page.
No. 3985-6/16
LC72191, 72191M, 72191JM
Continued from preceding page.
Pin No.
Symbol
I/O
7
8
IN0
IN1
Input*
16
15
HCTR
LCTR
Input
Input
Type
Function
Input port
• The values of the IN0 and IN1 input ports can be converted from parallel to serial and
output from the DO output pin.
General-purpose
counter
Frequency
measurement signal
input pin
• HCTR is selected when SC in the serial input data is set to 1.
• Input frequency range: 10 to 60 MHz (70 mVrms minimum)
• The signal is supplied to a general-purpose 20-bit binary counter after passing through a
divide-by-eight circuit. Therefore, the value of the counter is 1/8 of the frequency actually
input to HCTR.
• When HCTR is selected the LC72191 will function in frequency measurement mode
and the measurement period can be selected to be either 12 or 24 ms. (GT = 0: 12 ms,
1: 24 ms)
• The result of the measurement (the value of the general-purpose counter) can be output
MSB first from the DO output pin.
General-purpose
counter
Frequency or period
measurement signal
input pin
• LCTR is selected when SC in the serial input data is set to 0.
• When SF in the serial input data is set to 1:
— Frequency measurement mode is selected.
— Input frequency range: 15 to 500 kHz (70 mVrms minimum).
— The signal is supplied directly to the general-purpose counter without passing
through the internal divide-by-eight circuit.
— The measurement period is the same as for HCTR.
• When SF in the serial input data is set to 0:
— Period measurement mode is selected.
— Input frequency range: 1 Hz to 20 kHz (VIH = 0.7 VDD minimum, VIL = 0.3·VDD
maximum)
— The measurement can be selected to be for one or two cycles. If two cycle
measurement is selected the input frequency range becomes 2 Hz to 20 kHz.
(GT = 0: one cycle, 1: two cycles)
• Measurement results are output in the same manner as HCTR measurement results.
Note: * The high and low level input voltages for the CE, CL, DI, IN0 and IN1 pins are VIH = 2.2 to 6.5 V and VIL = 0 to 0.7 V, regardless of the power
supply voltage VDD.
Control Data Format (serial input data)
The LC72191 control data consists of 36 bits. All 36 bits must be input after power is applied to set up the LC72191
initial state. This is because the last two bits, while being unrelated to user functions, are data that switches the LSI test
modes.
Once the LC72191 has been initialized, the contents of the first 24 bits (D0 to CTEN) can be changed without changing
the contents of the last 12 bits (R0 to T1) by inputting data to DI in serial data input mode.
No. 3985-7/16
LC72191, 72191M, 72191JM
No.
Control block/data
Description
Related data
• This data sets up the programmable divider.
D0 to D15 is a binary value with D15 as the MSB.
The position of the LSB is changed by DV and SP as listed in the table below.
(1)
Programmable divider
data
D0 to D15
DV
SP
LSB
1
*
D0
Divisor setting
Actual divisor
256 to 65536
DV
SP
Twice the set value
0
1
D0
256 to 65536
The set value
0
0
D4
4 to 4096
The set value
* don’t care
When D4 is the LSB, bits D0 to D3 are ignored.
(2)
(3)
Output port data
O0 to O6
• Data that determines the states of the output ports OUT0 to OUT6. O0 determines the
OUT0 pin output. However, note that when O0 is 0, OUT0 will output a high level, and when O0
is 1, OUT0 will output a low level. O1 to O6 function in the same manner.
• These can be used for a wide range of purposes, including, for example, band switching
signals.
• When the TB bit is set to 1, the O0 data is ignored and the OUT0 pin outputs an 8 Hz clock
time base signal.
• Since the output port states are undefined when power is first applied, transfer the control data
quickly.
TB
General-purpose counter
initial data
CTEN
• Data that determines the operation of the general-purpose counter. When CTEN is 0, the 20-bit
binary counter (the general-purpose counter) is reset and the HCTR and LCTR pins are pulled
down to ground. When CTEN is set to 1, the general-purpose counter reset state is cleared and
the counter operates according to the SC bit (the general-purpose selection data). In this state,
the general-purpose counter will count either the HCTR or LCTR input signal.
• Since the general-purpose counter is reset by setting CTEN to 0, the result of a count operation
must be sent to the controller while CTEN is still 1.
SC
SF
GT
• Data that selects one of the ten LC72191 reference frequencies or sets the LC72191 to
backup mode in which PLL operation is disabled.
(4)
Reference frequency
data
R0 to R3
R0
R1
R2
R3
0
0
0
0
Reference frequency (kHz)
100
0
0
0
1
50
0
0
1
0
25
0
0
1
1
25
12.5
0
1
0
0
0
1
0
1
6.25
0
1
1
0
3.125
0
1
1
1
3.125
1
0
0
0
10
1
0
0
1
9
1
0
1
0
5
1
0
1
1
1
1
1
0
0
1
1
0
1
1
1
1
0
1
1
1
1
PLL inhibit state*
Note: * PLL inhibit (backup mode)
The programmable divider block is turned off, both the FMIN and AMIN pins are pulled
down to ground, and the charge pump outputs go to the floating state.
Continued on next page.
No. 3985-8/16
LC72191, 72191M, 72191JM
Continued from preceding page.
No.
Control block/data
Description
Related data
• DV selects the local oscillator input pin. (FMIN or AMIN)
• SP switches the input frequency range when AMIN is selected.
(5)
Divider selection data
DV
(6)
Sensitivity selection
data
SP
DV
SP
Input pin
Input frequency range (MHz)
1
*
FMIN
10 to 130
0
1
AMIN
2 to 40
0
0
AMIN
0.5 to 10
* don’t care
(7)
General-purpose
counter input pin
selection data
SC
(8)
General-purpose
counter
frequency/period mode
switching data
SF
• SC selects the input pin (HCTR or LCTR) for the general-purpose counter.
• SF selects the measurement type (frequency or period) when LCTR is selected.
When HCTR is selected, SF is ignored and the LC72191 operates in frequency measurement
mode.
DV
SP
Input pin
Measurement type
1
*
HCTR
Frequency measurement (sine wave)
0
1
LCTR
Frequency measurement (sine wave)
0
0
LCTR
Period measurement (pulse waveform)
CTEN
GT
* don’t care
(9)
General-purpose
counter count time
selection data
GT
• GT selects the measurement time in frequency measurement mode and the number of periods
in period measurement mode.
GT = 0: 12 ms/one period
GT = 1: 24 ms/two periods
(frequency measurement/period measurement)
(10)
Time base output
control data
TB
• When TB is set to 1 an 8 Hz 40% duty clock time base signal is output from OUT0. O0 bit is
ignored in this mode.
(11)
LSI test mode control
data
T0, T1
• T0 and T1 switch the LSI between test and normal operating modes. The test modes and have
no user related functions. Both T0 and T1 must always be set to 0.
Be sure to set both T0 and T1 to 0 after power is applied.
CTEN
SC
SF
O0
DO Output Format (serial data output)
The LC72191 includes a 28-bit internal shift register that can be used to output the following data from DO: the IN0 and
IN1 input port states, the general-purpose counter (20-bit binary counter) and the unlock detection circuit state.
The contents of the shift register is latched at the point that serial data output mode is selected.
No.
Data
(1)
Input port data
I0 and I1
• The values of the IN0 and IN1 input ports are latched into I0 and I1.
I0 ← IN0, I1 ← IN1
(2)
General-purpose
counter binary data
C19 to C0
• The C19 to C0 data is latched from value of the general-purpose 20-bit binary counter.
C19 ← 20-bit binary counter MSB
C0 → 20-bit binary counter LSB
PLL unlock state data
UL3 to UL0
• The UL3 to UL0 data is latched from the unlock detection circuit.
UL0: 1.11
UL1: 2.22
These bits are set to 1 if a phase difference in excess of these times (in µs) was detected.
UL2: 3.33
(for a 7.2 MHz crystal)
UL3: 0.55
(3)
Description
No. 3985-9/16
LC72191, 72191M, 72191JM
Serial Data I/O Methods
The LC72191 supports a total of three I/O modes: two control data input (serial data input) modes and one DO output
(serial data output) mode. Data I/O is performed after the mode has been determined.
The mode is selected by four data items (A0 to A3) synchronized with a clock (the CL pin) applied before the CE pin is
set high. The mode is determined when the CE pin goes high.
Mode
1
A3
0
A2
0
A1
0
A0
1
Item
Function
Serial data input (all bits)
• This mode is used to input all 36 bits of the control data (serial input data).
This mode is used for initialization following power on and to change data that
cannot be changed in mode 2. All 36 bits of the control data is input from the
LC72191 DI pin.
2
0
0
1
0
Serial data input
(partial input)
• This mode is used to input a subset (24 bits) of the control data (serial input
data).
This mode is used to change three data items: the programmable divider data
(D0 to D15), the output port data (O0 to O6) and the general-purpose counter
start data (CTEN), for a total of 24 bits. The other 12 bits of control data are not
changed by a mode 2 operation. (Use mode 1 when the other 12 bits must be
changed.)
3
0
0
1
1
Serial data output
• The DO output mode (serial data output) is used to output three data items from
the DO pin: the input port data, the general-purpose counter binary data and the
PLL unlock state data.
0 to 0
1 to 0
0 to 0
0 to 0
Invalid setting
• This mode is invalid and does not support any data input or output operations.
1. In the serial data input modes (modes 1 and 2), t1 ≥ 1.5 µs, t2 ≥ 0 µs, t3 ≥ 1.5 µs, and t4 < 1.5 µs.
• Mode 1: A total of 40 bits, the four mode selection bits and the 36 control data bits (from D0 to T1), are input from
the DI pin in synchronization with the clock (CL) signal.
• Mode 2: A total of 28 bits, the four mode selection bits and 24 control data bits (from D0 to CTEN), are input from
the DI pin in synchronization with the clock (CL) signal.
No. 3985-10/16
LC72191, 72191M, 72191JM
2. In serial data output mode (mode 3), t1 ≥ 1.5 µs, t2 ≥ 0 µs, t3 ≥ 1.5 µs, and t5 < 1.5 µs. (However, note that since the
DO pin is an n-channel open drain output, the transition time depends on the value of the pull-up resistor.)
• Mode 3: Serial output mode (mode 3) is selected by the four bits of mode selection data.
When the CE pin goes high, IO is output from the DO pin. After that, the internal shift register is shifted
and the next bit is output from the DO pin on each falling edge of the CL signal.
(Thus 27 clock cycles are required to output all data through the UL0 bit after CE goes high.)
When this mode is selected, at the point the CE pin falls to the low level, the DO pin will be forcibly set to
the high level. The DO pin will go low if the IN0 pin input changes state or if a general-purpose counter
measurement completes.
(General-purpose counter completion takes precedence over changes in the IN0 pin signal.)
Structure of the Programmable Divider
DV
SP
(A)
1
*
FMIN
Input pin
256 to 65536
Divisor setting
Twice the set value
Actual divisor
Input frequency range (MHz)
(B)
0
1
AMIN
256 to 65536
The set value
2 to 40
(C)
0
0
AMIN
4 to 4096
The set value
0.5 to 10
10 to 130
Note: 1. The actual divisor will be twice the set value when FMIN (A) is used.
For example, if the divisor setting is 1000 the actual divisor will be 2000 and if the divisor setting is 1001 the
actual divisor will be 2002. In other words, the channel skip will be twice the reference frequency.
2. To set the channel skips of 1, 5 and 9 kHz using FMIN (A), the crystal oscillator should be changed to 3.6
MHz. However, the times listed in the table that follows change since they are referenced to the crystal
oscillator frequency.
Note that care must be taken to prevent overtone oscillation when a 3.6 MHz crystal oscillator is used.
No. 3985-11/16
LC72191, 72191M, 72191JM
Xtal
Item
7.2 MHz
3.6 MHz
Time base clock
8 Hz
4 Hz
System clock
400 kHz
200 kHz
Frequency measurement time
24/12 ms
48/24 ms
Frequency measurement check signal
900 kHz
450 kHz
Reference frequencies
100, 50, 25, ......... 10, 9, 5, 1 kHz
50, 25, 12, 5, .......... 5, 4.5, 2.5, 0.5 kHz
Serial data I/O (CL)
t1 ≥ 1.5 µs, t3 ≥ 1.5 µs
t1 ≥ 3.0 µs, t3 ≥ 3.0 µs
Structure of the General-Purpose Counter
SC
SF
S1
1
*
HCTR
Input pin
Frequency measurement
Measurement item
Measurement frequency range
10 to 60 MHz (sine wave)
24 m/12 ms
GT (1/0)
S2
0
1
LCTR
Frequency measurement
15 to 500 kHz (sine wave)
24 m/12 ms
S3
0
0
LCTR
Period measurement
1 Hz to 20 kHz (pulse wave)
Two periods/one period
The LC72191 general-purpose counter is a 20-bit binary counter.
The value of the counter can be read out, msb first, from the DO pin.
When the general-purpose counter is used for frequency measurement, GT selects the measurement period to be one of
two periods, 12 or 24 ms. The frequency of the signal input to the HCTR or LCTR pin can be measured by determining
the number of pulses input to the general-purpose counter during the measurement period.
When the general-purpose counter is used for period measurement, the period of the signal input to the LCTR pin can be
measured by determining the number of check signal (900 kHz) cycles input to the general-purpose counter during one
or two periods of the signal input to the LCTR pin.
The general-purpose counter is started by setting CTEN to 1 in the serial data. While the serial data is acquired internally
in the LC72191 at the point the CE signal goes from high to low, the input to the HCTR or LCTR pin must be provided
within 2 ms after CE goes low.
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LC72191, 72191M, 72191JM
Next, the value of the general-purpose counter after the measurement completes must be read out while CTEN is still 1.
(The general-purpose counter is reset when CTEN is set to 0.)
Another point that requires care here is that before starting the general-purpose counter, it must be reset by setting
CTEN to 0.
Note that although signals input to the LCTR pin are transmitted directly to the general-purpose counter, signals input to
the HCTR pin are divided by eight internally before being transmitted to the general-purpose counter. Therefore the
value of the general-purpose counter will be 1/8 of the actual frequency input to the HCTR pin.
When counting intermediate frequency signals, always have the controller first check for the presence of the IF-IC SD
(station detect) signal and then turn on the IF counter buffer output only when the SD signal is present. Auto-search
techniques that use an IF count only are subject to stopping at frequencies where there is no station due to leakage output
from the IF counter buffer.
Note that although the DO pin is forced to the high level when the general-purpose counter is started (when CTEN is set
to 1), the DO pin automatically goes low when the measurement completes (after either 24 or 12 ms has elapsed or when
a signal has been applied for one or two periods). Therefore the DO pin can be used to check for measurement
completion.
Comparison of counting times
Catatog no.
Measurement time (tG)
GT = 0
GT = 1
Wait time (tW)
LC72191/M/JM
12 ms
24 ms
2 to 3 ms*
LC7219/M
60 ms
30 ms
10 to 15 ms
LC7218/M/JM
60 ms
120 ms
10 to 15 ms
Notes:* The value of the coupling capacitor must be under 1000 pF, since this product has a shorter wait time than the other products.
1. When the general-purpose is not used (when CTEN is 0) the DO pin can be used to check for changes in external
signals.
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LC72191, 72191M, 72191JM
• When mode 3 is specified and data is output through DO, DO will automatically go high after data output has
completed, i.e., when CE goes low.
• After that, DO goes low automatically when the IN0 signal changes state.
(That is, DO can be used to check for changes in an external signal input to IN0.)
2. When the general-purpose counter is used the DO pin can be used to check for completion of the general-purpose
counter measurement.
• When CTEN is set to 1, DO going low due to changes in IN0 is disabled and DO is set high automatically.
• DO is automatically set low when the general-purpose counter measurement completes.
(That is, DO can be used to check for measurement completion.)
PLL Unlock Data Read Out Procedure
The internal data UL(n) is set on the rising edge of øERROR
and reset on the rising edge of CE
.
The øERROR data UL(n) from before the previous CE
rising edge can be read out in mode 3 (data output).
In the example above, the data from the period between t0 and t1 is read out.
0.55 µs ≤
1.11 µs ≤
2.22 µs ≤
3.33 µs ≤
øERROR < 0.55 µs →
øERROR < 1.11 µs →
øERROR < 2.22 µs →
øERROR < 3.33 µs →
øERROR
→
UL0 : 1.11 µs
UL1 : 2.22 µs
UL2 : 3.33 µs
UL3 : 0.55 µs
UL (n)
3210
0000
1000
1001
1011
1111
Each bit is set to 1 according to øERROR as described above.
øERROR: the phase difference (for a 7.2 MHz crystal)
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LC72191, 72191M, 72191JM
Sample Application System
TV/FM/AM (When IF count is performed)
Note: 1. The coupling capacitors used on the FMIN, AMIN, HCTR, and LCTR pins should be between 50 and 100 pF.
However, a 1000 pF capacitor should be used for LCTR if frequencies under 100 kHz are to be used.
2. Coupling capacitors should be located as close to their pin as possible.
3. When counting intermediate frequency signals, always have the controller first check for the presence of the
IF-IC SD signal and then only turn on the IF counter buffer output only when the SD signal is present.
1. TV, 50 kHz steps
When the UHF RF = 637.75 MHz (IF = +10.7 MHz)
TV VCO = 648.45 MHz
PLL fref = 3.125 kHz
DV = 1, SP = * (FMIN selected)
Programmable divider divisor
Set N = 12969 (decimal).
2. FM, 100 kHz steps
When the FM RF = 90 MHz (IF = +10.7 MHz)
FM VCO = 100.7 MHz
PLL fref = 50 kHz
DV = 1, SP = * (FMIN selected)
Programmable divider divisor
Set N = 1007 (decimal).
3. AM, 10 kHz steps
When the AM RF = 1000 kHz (IF = +450 kHz)
AM VCO = 1450 kHz
PLL fref = 10 kHz
DV = 0, SP = 0 (AMIN, low speed measurement selected)
Programmable divider divisor
Set N = 145 (decimal).
*: Do not care
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LC72191, 72191M, 72191JM
■ No products described or contained herein are intended for use in surgical implants, life-support systems, aerospace
equipment, nuclear power control systems, vehicles, disaster/crime-prevention equipment and the like, the failure of
which may directly or indirectly cause injury, death or property loss.
■ Anyone purchasing any products described or contained herein for an above-mentioned use shall:
➀ Accept full responsibility and indemnify and defend SANYO ELECTRIC CO., LTD., its affiliates, subsidiaries and
distributors and all their officers and employees, jointly and severally, against any and all claims and litigation and all
damages, cost and expenses associated with such use:
➁ Not impose any responsibility for any fault or negligence which may be cited in any such claim or litigation on
SANYO ELECTRIC CO., LTD., its affiliates, subsidiaries and distributors or any of their officers and employees
jointly or severally.
■ Information (including circuit diagrams and circuit parameters) herein is for example only; it is not guaranteed for
volume production. SANYO believes information herein is accurate and reliable, but no guarantees are made or implied
regarding its use or any infringements of intellectual property rights or other rights of third parties.
This catalog provides information as of February, 1997. Specifications and information herein are subject to
change without notice.
No. 3985-16/16