Philips PCA1601U-10-F2, PCA1602T, PCA1602T-F2, PCA1603U-7, PCA1603U-F1 Datasheet

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DATA SH EET
Product specification Supersedes data of 1997 Apr 21 File under Integrated Circuits, IC16
1997 Dec 12
INTEGRATED CIRCUITS
PCA16xx series
1997 Dec 12 2
Philips Semiconductors Product specification
32 kHz watch circuits with EEPROM PCA16xx series
FEATURES
32 kHz oscillator, amplitude regulated with excellent frequency stability
High immunity of the oscillator to leakage currents
Time calibration electrically programmable and
reprogrammable (via EEPROM)
A quartz crystal is the only external component required
Very low current consumption; typically 170 nA
Detector for silver-oxide or lithium battery voltage levels
Indication for battery end-of-life
Stop function for accurate timing
Power-on reset for fast testing
Various test modes for testing the mechanical parts of
the watch and the IC.
GENERAL DESCRIPTION
The PCA16xx series devices are CMOS integrated circuits specially suited for battery-operated, quartz-crystal-controlled wrist-watches, with bipolar stepping motors.
ORDERING INFORMATION
Note
1. Figure 1 and Chapter “Package outline” show details of standard package, available for specified devices and for
large orders only. Chapter “Chip dimensions and bonding pad locations” shows exact pad locations for other delivery formats.
TYPE
NUMBER
PACKAGE
(1)
NAME DESCRIPTION VERSION
PCA1601U/10 chip on foil PCA1602T PMFP8 plastic micro flat package; 8 leads (straight) SOT144-1 PCA1603U/7 chip with bumps on tape PCA1604U chip in tray PCA1604U/10 chip on foil PCA1605U/7 chip with bumps on tape PCA1606U/10 chip on foil PCA1607U chip in tray PCA1608U chip in tray PCA1611U chip in tray PCA1621U/7 chip with bumps on tape PCA1621U/10 chip on foil PCA1622U chip in tray PCA1623U/7 chip with bumps on tape PCA1624U chip in tray PCA1625U/7 chip with bumps on tape PCA1626U chip in tray PCA1627U/7 chip with bumps on tape PCA1628U chip in tray PCA1629U/7 chip with bumps on tape
1997 Dec 12 3
Philips Semiconductors Product specification
32 kHz watch circuits with EEPROM PCA16xx series
PINNING
SYMBOL PIN DESCRIPTION
V
SS
1 ground (0 V) TEST 2 test output OSC IN 3 oscillator input OSC OUT 4 oscillator output V
DD
5 positive supply voltage M1 6 motor 1 output M2 7 motor 2 output RESET 8 reset input
Fig.1 Pin configuration, PCA16xxT, (PMFP8).
1 2 3 4
8 7 6 5
PCA16xxT
V
SS
TEST
OSC IN
OSC OUT
RESET M2 M1
V
DD
MSA973
FUNCTIONAL DESCRIPTION AND TESTING Motor pulse
The motor pulse width (t
P
) and the cycle times (tT) are
given in Chapter “Available types”.
Voltage level detector
The supply voltage is compared with the internal voltage reference V
LIT
and V
EOL
every minute. The first voltage
level detection is carried out 30 ms after a RESET.
Lithium mode
If a lithium voltage is detected (V
DD
V
LIT
), the circuit will operate in the lithium mode. The motor pulse will be produced with a 75% duty factor.
Silver-oxide mode
If the voltage level detected is between V
LIT
and V
EOL
, the
circuit will operate in silver-oxide mode.
Battery end-of-life
(1)
If the battery end-of-life is detected (VDD≤ V
EOL
), the motor pulse will be produced without chopping. To indicate this condition, bursts of 4 pulses are produced every 4 s.
Power-on reset
For correct operation of the Power-on reset the rise time of V
DD
from 0 V to 2.1 V should be less than 0.1 ms. All resettable flip-flops are reset. Additionally the polarity of the first motor pulse is positive: VM1− VM2≥ 0V.
(1) Only available for types with a 1 s motor pulse.
Customer testing
An output frequency of 32 Hz is provided at RESET (pin 8) to be used for exact frequency measurement. Every minute a jitter occurs as a result of time calibration, which occurs 90 to 150 ms after disconnecting the RESET from VDD.
Connecting the RESET to VDD stops the motor pulses leaving them in a HIGH impedance 3-state condition and a 32 Hz signal without jitter is produced at the TEST pin. A debounce circuit protects accidental stoppages due to mechanical shock to the watch (t
DEB
= 14.7 to 123.2 ms).
Connecting RESET to VSS activates Tests 1 and 2 and disables the time calibration.
Test 1, VDD>V
EOL
. Normal function takes place except the voltage detection cycle (tV) is 125 ms and the cycle time tT1 is 31.25 ms. At pin TEST a minute signal is available at 8192 times its normal frequency.
Test 2
(2)
, VDD<V
EOL
. The voltage detection cycle (tV) is
31.25 ms and the motor pulse period (tT2) = 31.25 ms. Test and reset mode are terminated by disconnecting the
RESET pin. Test 3, VDD> 5.1 V. Motor pulses with a time period of
tT3= 31.25 ms and n × 122 µs are produced to check the contents of the EEPROM. At pin TEST the motor pulse period signal (tT) is available at 1024 times its normal frequency. The circuit returns to normal operation when VDD< 2.5 V between two motor pulses.
(2) Only applicable for types with the battery end-of-life detector.
1997 Dec 12 4
Philips Semiconductors Product specification
32 kHz watch circuits with EEPROM PCA16xx series
Time calibration
Taking a normal quartz crystal with frequency 32768kHz, frequency deviation (f/f) of ±15 × 10−6 and CL= 8.2 pF; the oscillator frequency is offset (by using non-symmetrical internal oscillator input and output capacitances of 10 pF and 15 pF) such that the frequency deviation is positive-only. This positive deviation can then be compensated for to maintain time-keeping accuracy.
Once the positive frequency deviation is measured, a corresponding number ‘n’ (see Table 1) is programmed into the device’s EEPROM. This causes n pulses of frequency 8192 Hz to be inhibited every minute of operation, which achieves the required calibration.
The programming circuit is shown in Fig.2. The required number n is programmed into EEPROM by varying V
DD
according to the steps shown in Fig.3, which are explained below:
1. The positive quartz frequency deviation (f/f) is measured, and the corresponding values of n are found according to Table 1.
2. VDD is increased to 5.1 V allowing the contents of the EEPROM to be checked from the motor pulse period tT3 at nominal frequency.
3. V
DD
is decreased to 2.5 V during a motor pulse to
initialize a storing sequence.
4. The first VDD pulse to 5.1 V erases the contents of EEPROM.
5. When the EEPROM is erased a logic 1 is at the TEST pin.
6. VDD is increased to 5.1 V to read the data by pulsing VDD n times to 4.5 V. After the n edge, VDD is decreased to 2.5 V.
7. VDD is increased to 5.1 V to store n bits in the EEPROM.
8. VDD is decreased to 2.5 V to terminate the storing sequence and to return to operating mode.
9. VDD is increased to 5.1 V to check writing from the motor pulse period tT3.
10. VDD is decreased to the operation voltage between two motor pulses to return to operating mode. (Decreasing VDD during the motor pulse would restart the programming mode).
The time calibration can be reprogrammed up to 100 times.
Table 1 Quartz crystal frequency deviation, n and t
T3
Notes
1. Increments of 2.03 × 10−6/step.
2. Increments of 122 µs/step.
FREQUENCY
DEVIATION
f/f
(× 10
6
)
NUMBER OF
PULSES
(n)
t
T3
(ms)
0
(1)
0 31.250
(2)
+2.03 1 31.372 +4.06 2 31.494
... ... ...
+127.89 63 38.936
Fig.2 Circuit for programming the time calibration.
MSA975
V
DD
M1
M2
RESET
V
SS
TEST
OSC IN
OSC OUT
M
PCA16xx
SERIES
1
2
3
4
8
7
6
5
32 kHz
SIGNAL GENERATOR
1997 Dec 12 5
Philips Semiconductors Product specification
32 kHz watch circuits with EEPROM PCA16xx series
MSA948
V
DDP
123 n
t = 1 µs
edge
0.1 ms
min.
t
T3
CHECKING
STORINGDATA INPUTERASURECONTENT CHECKING
1 2
9 10
3 4 5 6 7 8 9 10
I
DD
V (V)
DD
0 (V )
SS
2.5
1.5
4.5
5.1
(1) (1) (1) (1)
t = 5 ms
E
t = 5 ms
S
(1) Rise and fall time should be greater than 400 µs/V for immediately correct checking.
Fig.3 V
DD
for programming.
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