[0001] This invention relates to analog electronic watches having an additional function
indication, such as a chronograph indication, a timer indication or an alarm indication.
[0002] The addition of function indications, such as chronograph, alarm, timer or the like,
to analog electronic watches is known. For the indication of such functions, a small
second hand, alarm hour and minute hands and other hands are used in addition to ordinary
second, hour and minute hands, and a small window for exclusive use is provided at
an arbitrary eccentric position on the face such as, for example, along the position
of the hour hand at 6 o'clock or 9 o'clock, thereby indicating a function such as
alarm time or the like.
[0003] An auxiliary stem and a button for switching function modes are used in addition
to the ordinary stem.
[0004] The provision of such function indications results in variations of watch design,
to cope with diverse consumers' needs and preference.
[0005] Such analog electronic watches are exemplified and so disclosed in Japanese Laid-Open
Patent Application No. 286783/1986, Japanese Laid-Open Patent Application No. 294388/1986,
and Japanese Laid-Open Utility Model Application No. 26191/1986.
[0006] However, in a prior art multi-functional electronic watch, and additional individual
movement structure and IC chip for drive are required for each function added. That
is, the movement structure and disposition of parts must be changed whenever there
is an addition or reduction of function indications or a change in specification and
the IC chip must be replaced accordingly in each case. Thus, the manufacturer is forced
to produce a variety of goods in small quantities so as to comply with consumers'
needs and provide variations in watch design and function.
[0007] In such circumstances, the prior art multi-functional electronic watch involves
extra die cost and working cost when there is a change in parts, mask cost for an
IC chip change and further a cost for design change, thus resulting in high cost for
such a multi-functional electronic watch. Further, redundancy allowed in the disposition
of parts and in IC chip specification so as to satisfy various requirements by a single
model of electronic watch, inevitably lead to a large sized construction and an increase
in cost of the watch.
[0008] Thus, the prior art multi-functional electronic watch cannot comply economically
with diverse requirements.
[0009] The present invention seeks to remove this defect and others, and its object is to
provide a multi-functional electronic watch, effective in lessening the load on design
and manufacture, causing no requirement for increased cost and size, satisfying diverse
market requirements easily and ensuring design efficiency.
[0010] According to the invention, there is provided a multi-functional analog watch having
a step motor for driving hands indicating ordinary time, at least one or more step
motor for driving means to indicate at least one additional function, a gear train
between the motor and the hands for indicating ordinary time, and at least one more
gear train between a step motor and means for indicating the additional function,
characterised in that the ordinary time is indicated by hands rotatable about a central
axis, and that the means for indicating at least one additional function comprises
at least one hand rotatable about an axis eccentric to the central axis.
[0011] Other aspects of the invention will be defined in claims 2 to 13 appended hereto.
[0012] From another aspect, the invention includes a multi-functional analog electronic
watch having a step motor for indicating ordinary time and at least one or more step
motors for indicating additional functions, a gear train for indicating ordinary time
and at least one or more gear trains for indicating the additional functions, and
a micro-computer including a program memory, ordinary time and the additional functions
being indicated at arbitrary positions of at least one or more of a movement centre
position, a position on an axis in the 12 o'clock direction, a position on an axis
in the 3 o'clock direction, a position on an axis in the 6 o'clock direction, and
a position on an axis in the 9 o'clock direction according to a number and disposition
of the additional function indicating step motors, and disposition of the ordinary
time indicating gear train and the additional function indicating gear trains, and
actuating signals being generated from the micro-computer in accordance with software
in the program memory, to operate the indications at corresponding positions.
[0013] From yet another aspect, the invention includes a multi-functional electronic watch
having a step motor for indicating ordinary time, at least one or more step motors
for indicating additional functions, a gear train for indicating ordinary time and
at least one or more gear trains for indicating the additional functions, and a micro-computer
including a program memory, ordinary time and the additional functions being indicated,
respectively, at a centre position and at one of a plurality of arbitrary positions
eccentric to the centre position according to the number and disposition of the step
motors for indicating additional functions and of the gear train for indicating ordinary
time and the gear trains for indicating the additional functions.
[0014] The micro-computer may generate an actuating signal as instructed by software in
the program memory, thereby operating correspondingly the ordinary time indicating
and additional function indicating positions.
[0015] The invention further includes a multi-functional electronic watch having a plurality
of step motors, alarm means and a plurality of external operation means, a first step
motor for driving hour/minute hands for indicating ordinary time which are disposed
one upon the other at the centre of a watch, and a small second hand for indicating
seconds of ordinary time which is disposed at a position eccentric to the centre of
the watch, a second step motor for driving a chronograph second hand disposed over
the hour/minute hands at the centre of the watch, a third step motor for driving a
chronograph minute hand disposed at a position eccentric to the centre of the watch,
a fourth step motor for driving alarm hour/minute hands for indicating an alarm time
which are disposed at a position eccentric to the centre of the watch, a first stem
disposed on an outer peripheral portion of the watch, a first switch operating button
and a second switch operating button disposed on an outer peripheral portion adjacent
the chronograph minute hand indication, a second stem and a third switch operating
button disposed on an outer peripheral portion adjacent the alarm time indication.
The alarm hour/minute hands may have a time change function capable of selecting an
alarm set time or ordinary time.
[0016] Minutes and seconds of the timer may be indicated on the same hands as the chronograph
seconds and minutes, respectively, by reversing the second step motor and the third
step motor. One minute of timer residual time may be indicated by increasing the speed
of the chronograph second hand disposed at the centre of the watch and stopping the
chronograph minute hand.
[0017] The chronograph second hand disposed at the centre of the watch may vary in drive
spacing according to an indication function. The chronograph second may be indicated
by a five step drive per second of the chronograph second hand disposed at the centre
of the watch.
[0018] The external operation member for correcting the alarm time indicated, and the external
operation member for correcting the ordinary time are preferably disposed at different
positions.
[0019] Ordinary time indicated on the alarm hands may be corrected by turning the second
stem.
[0020] The first stem may be the external operation member having a correcting function
of basic time keeping. The second stem may have a plural stage of pull positions and
different operating functions according to the pull position selected.
[0021] The invention is described further, by way of example, with reference to the accompanying
drawings, in which:-
Figure 1 is a block diagram representing an IC chip for an analog electronic watch
in one embodiment of the invention;
Figure 2 is a block diagram representing a chronograph circuit forming part of the
circuit of Figure 1;
Figure 3 is a block diagram representing a motor drive controlling circuit forming
part of the circuit of Figure 1;
Figure 4 is a block diagram representing a drive reference signal forming circuit
forming part of the circuit of Figure 3;
Figures 5, 6, 7 and 8 are timing charts of motor driving pulses generated from first,
second, third and fourth driving pulse shaping circuits respectively, forming part
of the circuit of Figure 3;
Figure 9 is a block diagram representing one of four motor clock control circuits
forming part of the circuit of Figure 3;
Figure 10 is a plan view of one embodiment of an analog electronic watch according
to the invention;
Figure 11 is a sectional view of gear trains in the watch of Figure 10 for driving
hands to indicate ordinary time in hours and minutes;
Figure 12 is a sectional view of a gear train in the watch of Figure 10, for driving
a hand to indicate ordinary time in seconds;
Figure 13 is a sectional view of a gear train in the watch of Figure 10, for driving
a stopwatch second hand;
Figure 14 is a sectional view of gear trains in the watch of Figure 10, for driving
a hand to indicate a chronograph minute and a timer second;
Figure 15 is a sectional view of a gear train in the watch of Figure 10, for driving
hands to indicate an alarm set time;
Figure 16 is a circuit connection diagram of the watch of Figure 10;
Figure 17 is a front view of a complete multi-function electronic watch according
to one embodiment of the invention;
Figures 18 (a) and 18 (b) are flow charts of alternative steps for indicating ordinary
time;
Figures 19 (a) and 19 (b) are flow charts of alternative steps of a chronograph function;
Figures 20 (a) and 20 (b) are flow charts of alternative steps of a timer function;
Figures 21 (a), 21 (b) and 21 (c) are flow charts of alternative steps of an alarm
function;
Figures 22 (a), 22 (b) and 22 (c) are flow charts of alternative steps of driving
methods of the motor;
Figure 23 is a plan view, similar to Figure 10, of a second embodiment of a multi-functional
electronic watch according to the invention;
Figure 24 is a sectional view of a gear train in the watch of Figure 23 for driving
a hand to indicate ordinary time in seconds;
Figure 25 is a front view, similar to Figure 17, of the second embodiment of a multi-functional
electronic watch;
Figure 26 is a plan view, similar to Figure 10, of a third embodiment of a multi-functional
electronic watch according to the invention;
Figure 27 is a sectional view of a gear train in the watch of Figure 26 for driving
a hand to indicate ordinary time in seconds; and
Figure 28 is a front view, similar to Figure 17, of the third embodiment of a multi-functional
electronic watch according to the invention.
[0022] A CMOS-IC chip 20 (Figure 1) is a one chip micro-computer for an analog electronic
watch with a program memory 202, a data memory 204, four motor drivers 213, 214, 215
and 216, a motor drive controlling circuit 212, a sound generator 210, an interrupt
control circuit 218 and other circuits integrated on one chip around a core CPU 201.
[0023] The core CPU 201 comprises an ALU, a register for arithmetic operations, an address
controlling register, a stack pointer, an instruction register, an instruction de-coder
and other functional circuits, and is connected to peripheral circuits through an
address bus
adbus and a data bus
dbus according to a memory-mapped I/O system.
[0024] The program memory 202 consists of a mask read only memory ROM of 2,048 words x 12
bits, storing software for operating the IC, and has an address decoder 203.
[0025] The data memory 204 consists of a random access memory RAM of 112 words x 4 bits
which is used for various timers, counters for storing hand position of each pointer
and others, and has an address de-coder 205.
[0026] An oscillator circuit 206 oscillates at 32,768 Hz with a tuning fork crystal resonator
connected to terminals
Xin and
Xout as an oscillation source.
[0027] A first divider circuit 208 divides the 32,768 Hz signal 0̸32k generated from the
oscillator circuit 206 in sequence and generates a 1 kHz signal 0̸1k, a 512 Hz signal
0̸512, a 256 Hz signal 0̸256, and a 16 Hz signal 0̸16. An oscillation stop detection
circuit 207 is connected to receive the signal 0̸1k and, when a stop of oscillation
of the oscillator circuit 206 is detected, applies a re-set to the system.
[0028] A second divider circuit 209 divides the signal 0̸16 from the first divider circuit
208 in sequence into 8 Hz, 4Hz, 2 Hz and 1 Hz signals, which can be read into the
core CPU 201 by the software.
[0029] The 16 Hz signal 0̸16, 8 Hz signal 0̸8, and 1 Hz signal 0̸1 are used as a time interrupt
(
Tint) for processing such as time keeping or the like. The time interrupt (
Tint) is generated at the fall of each signal. Read, re-set and mask of each interrupt
source are all effected by the software, and re-set and mask are read individually
at every source.
[0030] The sound generator 210 can generate a buzzer driving signal to a terminal AL. Driving
frequency, ON/OFF operation and sound pattern of the buzzer driving signal can be
controlled by the software.
[0031] The chronograph circuit 211 (Figure 2) provides a 1/100 sec chronograph, though the
drive of the 1/100 sec hand is controlled by hardware to lighten the load on the software.
[0032] The circuit 211 includes a clock forming circuit 2111 which forms 100 Hz signal 0̸100
working as a reference clock for chronography from 512 Hz signal 0̸512, and a clock
pulse
Pfc 100 Hz and 3.91 ms in pulse width for forming 1/100 sec hand driving pulse
Pf. A 50-proceeding chronograph counter 2112 counts signals 0̸100 passing through an
AND gate 2119 and is re-set on a chronograph re-set signal
Rcg generated by a control signal forming circuit 2118. A register 2113 holds the contents
of the chronograph counter 2112, when a split indication command signal
Sp is generated by the control signal forming circuit 2118. A 50-proceeding hand position
counter 2114 stores 1/100 sec hand indication position of the 1/100 sec hand by counting
1/100 sec hand driving pulses
Pf from a 1/100 sec hand drive controlling circuit 2117 and is re-set by a signal
Rhnd from the control signal forming circuit 2118 to store a zero position on the 1/100
sec hand.
[0033] An identity detection circuit 2115 compares the contents of the register 2113 and
of the hand position counter 2114 and generates an identity signal
Dty when identity is detected. A zero position detection circuit 2116 generates a zero
detection signal
Dt0̸ upon detection of zero in the hand position counter 2114.
[0034] The control signal forming circuit 2118 receives instructions over the bus BUS and
forms and generates a start signal
St, a chronograph re-set signal
Rcg, a split signal
Sp, a drive signal
Drv and the zero position signal
Rhnd. The start signal
St is passed to AND gate 2119 and to circuit 2117 to command a measurement start or
stop according to a command of the software. The split signal
Sp is passed to register 2113 and circuit 2117 to command a split indication or split
indication release. The chronograph re-set signal
Rcg is passed to counter 2112 to command a re-set of measurement. The zero position signal
Rhnd is passed to counter 2114 to store a zero position of the 1/100 sec hand. The drive
signal
Drv is passed to circuit 2117 to command operation or inoperation of the 1/100 sec hand.
The 1/100 sec hand drive controlling circuit 2117 receives clock pulses
Pfc from circuit 2111 and passes clock pulses
Pfc when the contents of the chronograph counter 2112 and the hand position counter 2114
are identical in the state when the 1/100 sec hand operates and also during measuring,
that is when signals
Dty and
Drv or
St are up. The circuit 2117 also passes clock pulses
Pf when the contents of the register 2113 and the hand position counter 2114 are not
identical at the time of split indication and also stop of measuring, that is when
signal
Dty is down and signal
Sp is up or signal
St is down. The circuit 2117 also passes clock pulses
Pf when the contents of the hand position counter 2114 is other than zero in the state
when the 1/100 sec hand is not operating and also during measuring, that is when signal
Dt0̸ is down and signal
Drv is down or signal
St is up. The clock pulses
Pf are supplied to motor driver 215 (Figure 1) so that the 1/100 sec hand is ready for
driving only by a step motor C. Further, a chronograph interrupt
CGint (Figure 2) is generated on a 5 Hz carry signal 0̸5 coming from the chronograph counter
2112, and a measurement after 1/5 seconds is ready for processing by the software.
[0035] The motor drive controlling circuit 212 (Figure 3) generates motor driving pulses
for each motor driver according to commands from the software.
[0036] The circuit 212 includes a motor drive system controlling circuit 219 which stores
a drive system for each motor and according to commands from the software forms and
generates control signals, namely, signal
Sa for selecting a forward drive I, signal
Sb for selecting a forward drive II, signal
Sc for selecting a reverse drive I, signal
Sd for selecting a reverse drive II, and signal
Se for selecting a forward corrective drive.
[0037] The circuit 212 also includes a drive reference signal forming circuit 220 (Figure
4) for forming and generating a drive reference clock signal
Cdrv according to commands from the software over the bus BUS. The circuit 220 includes
a 3-bit register 2201 which stores data supplied over the data bus
dbus for deciding the frequency of the driving reference clock signal
Cdrv according to the output signal of an address de-coder 2202 receiving addresses over
the address bus
adbus from the software. The circuit 220 also includes a 3-bit register 2203 which is loaded
with the data in the register 2201 at the fall of the driving reference clock signal
Cdrv generated by a programmable dividing circuit 2205. The circuit 220 also includes
a de-coder 2204 generating numerals 2, 3, 4, 5, 6, 8, 10 and 16 in binary form corresponding
to data stored in the register 2203. The programmable dividing circuit 2205 divides
the 256 Hz signal 0̸256 generated from the first divider circuit 208 by
n, being the numeral generated by the de-coder 204. Accordingly, the drive reference
signal forming circuit 220 is capable of selecting the frequency of the drive reference
clock signal
Cdrv from among eight kinds, namely, 128 Hz., 85.3 Hz, 64 Hz, 51.2 Hz, 42.7 Hz, 32 Hz,
25.6 Hz and 16 Hz. The frequency of the drive reference clock signal
Cdrv is changed at the point in time when data is loaded into the register 2203, and the
data is loaded into the register 2203 synchronously with the drive reference clock
signal
Cdrv. Therefore an interval of 1/
fa will be secured when the frequency
fa is switched to the next frequency
fb.
[0038] The circuit 212 also includes four motor clock controlling circuits 226, 227, 228,
229 which control driving pulse numbers of step motor A, step motor B, step motor
C, step motor D, respectively, according to commands from the software. As the circuits
are identical, only one circuit 226 (Figure 9) will be described in detail. The circuit
226 includes a 4-bit register 2261 which stores a driving pulse number commanded by
the software. A 4-bit up-counter 2262 counts drive reference clock signals
Cdrv passing through AND gate 2274, and is re-set by a control signal. A control signal
forming circuit 2272 receives instructions over the address bus
adbus, and forms and generates a signal
Sset for setting a driving pulse number on the data bus
dbus in the register 2261 according to commands from the software, a signal
Sread for reading data of the up-counter 2262, and a signal
Sreset for re-setting the register 2261 and the up-counter 2262. The signal
Sread is supplied to an inverter 2273 whose output is to the AND gate 2274, so that the
driving reference clock signals
Cdrv are prohibited from passing the AND gate 2274. A two-way switch 2271 is turned to
ON when the signal
Sread is generated, thus applying data of the up counter 2262 onto the databus
dbus. In this case, the register 2261 and up-counter 2262 must be re-set after reading
by the signal
Sreset.
[0039] An identity detection circuit 2263 compares the contents of the register 2261 and
the up-counter 2262 and generates an identity signal
Dy when the contents are identical. An all-1 detection circuit 2264 generating an all-1
detection signal D15 when the contents of the register 2261 are all 1s. A motor driving
pulse forming trigger signal generation circuit 2265 comprises inverters 2266 and
2267, a 3-input AND gate 2268, a 2-input AND gate 2269 and a 2-input OR gate 2270.
[0040] The circuit 2265 receives clock signals
Cdrv supplied as inputs to AND gates 2268 and 2269, the identity signal
Dy as input to inverter 2266 whose output is one input of AND gate 2268, and the all-1
detection signal D15 as input to AND gate 2269 and as input to inverter 2267 whose
output is one input to AND gate 2268. The outputs of AND gates 2268 and 2269 are ORed
in OR gate 2270 whose output is a motor trigger signal
Tr. When a number, other than all 1s, is set in register 2261, which number differs
from that in register 2262, trigger signals
Tr are generated through AND gate 2268 until the numbers agree, when the identity signal
Dy stops such generation. When the register 2261 is set to all 1s, the circuit 2265
generates trigger signals
Tr repeatedly through AND gate 2269 even when an identity signal
Dy is generated.
[0041] When the identity detection circuit 2263 detects identity or when the pulse number
is set at zero, a motor control interrupt
Mint is generated, which interrupt can be read by the software, and can be re-set after
reading.
[0042] The circuit 212 (Figure 3) includes four trigger forming circuits 230, 231, 232 and
233, each receiving a signal
Sa,
Sb,
Sc,
Sd or
Se from circuit 219 and passing a trigger signal
Tr generated from the corresponding motor clock controlling circuit as trigger signals
Sat,
Sbt,
Sct,
Sdt,
Set for drive pulse controlling circuits 221, 222, 223, 224 and 225 to form motor driving
pulses
Pa, Pb, Pc, Pd, Pe correspondingly to drive system control signals
Sa,
Sb,
Sc,
Sd,
Se generated from the motor drive system controlling circuit 219.
[0043] When the forward drive I and the reverse drive are carried out continuously, the
frequency of the driving reference clock
Cdrv is limited to below 64 Hz. The first drive pulse forming circuit 221 forms and generates
the driving pulse
Pa for forward drive I (Figure 5). The second drive pulse forming circuit 222 forms
and generates the driving pulse
Pb for forward drive II (Figure 6). The third drive pulse forming circuit 223 forms
and generates the driving pulse
Pc for the reverse drive I (Figure 7). The fourth drive pulse forming circuit 224 forms
and generates the driving pulse
Pd for reverse drive II (Figure 8). The fifth drive pulse forming circuit 225 forms
and generates a pulse group
Pe for corrective drive, comprising ordinary driving pulse Pl, correction driving pulse
P2, pulse P3 at the time of AC magnetic field detection, AC magnetic field detecting
pulse SP1, rotation detecting pulse SP2, as disclosed in Japanese Laid-Open Patent
No. 260883/1985.
[0044] Four motor driving pulse selection circuits 234, 235, 236 and 237 (Figure 3), select
and generate driving pulses PA, PB, PC and PD, respectively, necessary for a step
motor from among the motor driving pulses
Pa, Pb, Pc, Pd, Pe generated by the driving pulse forming circuits 221 to 225, corresponding to the
drive system control signals
Sa,
Sb,
Sc,
Sd or
Se received.
[0045] The motor drivers 213, 214, 215 and 216, each drive a step motor by passing motor
driving pulses PA, PB, PC and PD, respectively, coming from the motor driving pulse
selection circuit 212 alternately to two output terminals of each motor driver.
[0046] An input control and re-set signal forming circuit 217 receives switched inputs at
terminals A, B, C, D, RA1, RA2, RB1 and RB2, and inputs at terminals K, T and R. The
circuit 217 also receives data and instructions on bus BUS and any re-set input from
the oscillation stop detection circuit 207.
[0047] The interrupt control circuit 218 operates to give precedence to each switch interrupt
SWint, chronograph interrupt
CGint, motor control interrupt
Mint, storage before reading, and re-set R after reading, by issuing a signal INT. A constant
voltage circuit 200 provides a low constant voltage of about 1.2 V at terminal VS1
from a battery voltage of about 1.58 V impressed across terminals VDD and VSS. If
there is a switched input at any one of the terminals A, B, C, D, RA1, RA2, RB1 or
RB2, a switch interrupt signal
SWint is generated. In this case, read and re-set of the interrupt source are carried out
by the software. Then, each input terminal is pulled down to the level of terminal
VSS representing data 0, where data 1 is represented by the level of terminal VDD.
[0048] The terminal K is that for switching specifications, and two kinds of specifications
can be selected according to the data on terminal K. Then, the data on the terminal
K is read by the software.
[0049] The terminal R is that for system re-setting, and when the terminal R is at the level
of terminal VDD, the core CPU 201, the divider circuits 208 and 209 and other peripheral
circuits are initialised by the hardware.
[0050] The terminal T is that for converting the test modes, and by inputting a clock pulse
to the terminal T with the terminal RA2 at the level of terminal VDD, sixteen test
modes for testing peripheral circuits can be changed. The main test mode comes in
a forward drive I ensuring mode, a forward drive II ensuring mode, a reverse drive
I ensuring mode, a reverse drive II ensuring mode, a corrective drive ensuring mode,
a chronograph 1/100 sec ensuring mode and others, and in these ensuring modes, the
motor driving pulse is generated automatically to each motor driving pulse output
terminal.
[0051] The system can be re-set by connecting the terminal R to the level of terminal VDD
and also by closing the switches concurrently otherwise. In the IC, the system will
be re-set forcibly by hardware when A or C, and B and RA2 are closed concurrently,
and also when one of A, B and C, and RA2 and RB2 are closed concurrently.
[0052] Then, functions to re-set the divider circuit and other peripheral circuits are available
by the software, and when the peripheral circuits are re-set, the divider circuits
will also be re-set.
[0053] Thus, the CMOS-IC 20 has the following features for the drive of step motors, and
is extremely effective as IC chip for multi-hand type multi-functional analog electronic
watches:-
1. the motor drivers 213, 214, 215 and 216, so that the four step motors can be driven
concurrently;
2. the motor drive system controlling circuit 219, the drive pulse forming circuits
221 to 225 and the motor drive pulse selection circuits 234 to 237, so that three
kinds of forward drive and two kinds of reverse drive on each of the four step motors
can be effected by the software;
3. the drive reference signal forming circuit 220, so that the drive speed of each
step motor can be arbitrarily changed by the software; and
4. the motor clock controlling circuits 226 to 229 each corresponding to a step motor,
so that a driving pulse number can be set arbitrarily for each step motor.
[0054] An embodiment of a multi-functional analog electronic watch (Figure 10) according
to the invention incorporates a CMOS-IC 20 as hereinbefore described. The watch includes
a base plate 1 formed of a plastics resin material, and a silver oxide battery 2 (SR927W).
There are four step motors A, B, C, and D, referenced in Figure 10 as 3, 15, 27 and
32. The step motor 3 for indicating ordinary time, comprises a magnetic core 3a of
high permeability material, a coil block 3b consisting of a coil wound on the magnetic
core 3a, a coil lead substrate having the opposite ends processed to be conductive
and a coil frame, a stator 3c formed of high permeability material, and a rotor 4
consisting of a rotor magnet and a pinion 4a (Figure 11).
[0055] A fifth wheel 5 has a gear 5a engaged with the pinion 4a, and a pinion 5b engaged
by a gear 6a of a fourth wheel 6. The wheel 6 has a pinion 6b engaged by a gear 7a
of a third wheel 7 which also has a pinion 7b engaged by a gear 8a of a minute wheel
8. The wheel 8 has a pinion 8b engaged by a gear 9a of an intermediate wheel 9 having
a pinion 9b engaged by a gear 10a of an hour wheel 10. The minute wheel 8 and hour
wheel 10 have their axes disposed centrally of the watch face and have noses projecting
therethrough carrying minute and hour hands 11 and 12, respectively. The various pinions,
wheels and gears of the gear train are mounted on bearings in the base plate 1 and
a spaced plate 53 (Figures 11 to 15). The plate 53 (Figure 15) is recessed to receive
a circuit substrate 54 held in place by a plate 52.
[0056] The reduction ratio between the rotor pinion 4b and the minute wheel gear 8a is 1/1800,
so that the minute wheel 8 and hand 11 rotate once for every 1800 rotations of the
rotor 4. If the rotor 4 rotates once in two seconds, that produces a single revolution
of the wheel 8 per 3600 seconds or 60 minutes or one hour. The reduction ratio between
the minute pinion 8b and the hour wheel gear 10a is 1/12, so that with the rotor 4
rotating once in two seconds, the hour wheel rotates once in twelve hours.
[0057] The pinion 5b of the fifth wheel 5 (Figure 12) is also engaged by a gear 13a of a
small second wheel 13 whose axis of rotation is disposed eccentrically of the watch
face and along the position of the hour hand at 9 o'clock (Figure 17). The wheel 13
has a nose projecting through the watch face 41 (Figure 12) and carrying a small second
hand 14. The reduction gear ratio between the rotor pinion 4a and the small second
gear 13a is 1/30, and thus the small second wheel 13 turns once per 60 seconds when
the rotor 4 rotates once per two seconds, thereby indicating seconds of ordinary time.
[0058] The step motor 15 (Figure 10) for chronograph second hand indication, comprises a
magnetic core 15a of high permeability material, a coil block 15b consisting of a
coil wound on the magnetic core 15a, a coil lead substrate with the opposite ends
processed to be conductive and a coil frame, a stator 15c consisting of high permeability
material, and a rotor 16 consisting of a rotor magnet and a rotor pinion 16a (Figure
13).
[0059] The rotor pinion 16a is engaged by a gear 17a of a chronograph first intermediate
wheel 17 having a pinion 17b engaged by a gear 18a of a chronograph second intermediate
wheel 18. The wheel 18 has a pinion 18b engaged by a gear 19a of a chronograph wheel
19. The chronograph wheel 19 is disposed centrally of the watch and has a nose projecting
through the noses of the minute and hour wheels 8 and 10, and carries a hand 21. The
wheel 19 is urged into engagement with the wheel 8 by a spring 65 (Figures 11 to 15)
pressing on a bearing portion projecting through the plate 53. The reduction gear
ratio between the rotor pinion 16a and the chronograph gear 19a is 1/150. The rotor
16 rotates two and a half times or 900° per second on electrical signals from CMOS-IC
20, so that the chronograph wheel 19 rotates 6° per second, or five steps of 1.2°,
thereby indicating 60 chronograph seconds per revolution. The hand 21 functions as
a timer set hand for timer setting at the same time in a timer operation described
hereinafter.
[0060] The step motor 27 (Figure 10) for minute indication of the chronograph and second
indication of an elapsed time of the timer, comprises a magnetic core 27a of high
permeability material, a coil block 27b consisting of a coil wound on the magnetic
core 27a, a coil lead substrate with the opposite ends processed to be conductive
and a coil frame, a stator 27c consisting of high permeability material, and a rotor
28 consisting of a rotor magnet and a rotor pinion 28a (Figure 14). The rotor pinion
28a is engaged by a gear 29a of a chronograph minute intermediate wheel 29 having
a pinion 29b engaged by a gear 30a of a chronograph minute wheel 30. The chronograph
minute wheel 30 is disposed to rotate on an axis eccentric to the watch face and along
the position of the hour hand at 12 o'clock. A minute indication of the chronograph
and a second indication of an elapsed time of the timer are made on that axis. The
reduction gear ratio between the rotor pinion 28a and the chronograph minute gear
30a is 1/30. In the chronograph mode, the rotor 28 rotates once per minute on electrical
signals from CMOS-IC 20. Accordingly, the chronograph minute wheel 30 rotates 12°
per minute, or once every half hour, thus realising a chronograph minute indication
of 30 minutes. The wheel 30 has a nose projecting through the watch face 41 and carrying
a chronograph minute hand 31 for chronograph minute indication. By combining the indications
of the chronograph hands 21 and 31, a chronograph indication is realised with 1/5
seconds as minimum reading unit and 30 minutes as maximum.
[0061] In the timer mode, the rotor 28 rotates counter to that of chronograph mode once
every two seconds on electrical signals from CMOS-IC 20. Thus the chronograph minute
hand 31 rotates once counter-clockwise every 60 seconds in steps of one second, thus
indicating seconds of an elapsed time of the timer in a 60 seconds rotation. At the
same time, the rotor 16 rotates two and a half times per minute counter to that of
chronograph mode on electrical signals from the CMOS-IC 20. Accordingly, the central
chronograph hand 21 turns counter clockwise at 6° per minute, thus indicating minutes
of elapsed time of the timer. The CG minute hand 31 driven by the step motor 27 acts
as the 1/100 second hand referred to in connection with Figure 2, when controlled
by software.
[0062] The watch has first and second manually operable stems 22 and 23 (Figure 17) and
three switch operating buttons 24, 25 and 26. In setting the timer, the second stem
23 is placed in a first state and the rotor 16 rotates through 180° in five steps
whenever a button 25 is pushed once to close the switch connected to terminal B, so
that the chronograph hand 31 turns 6° representing one minute. Thus a timer set time
as long as 60 minutes can be shown.
[0063] The step motor 32 (Figure 10) comprises a magnetic core 32a of high permeability
material, a coil block 32b consisting of a coil wound on the magnetic core 32a, a
coil lead substrate with the opposite ends processed to be conductive and a coil frame,
a stator 32c consisting of high permeability material, and a rotor 33 consisting of
a rotor magnet and a rotor pinion 33a (Figure 15). The rotor pinion 33a is engaged
by a gear 34a of an alarm intermediate wheel 34 having a pinion 34b engaged by a gear
35a of an alarm minute wheel 35. The wheel 35 has a pinion 35b engaged by a gear 36a
of a third alarm wheel 36 having a pinion 36b engaged by an alarm hour wheel 37. The
reduction ratio between the rotor pinion 33a and the alarm minute gear 35a is 1/30,
and the reduction ratio between the alarm minute pinion 35b and the alarm hour wheel
37 is 1/12. The wheels 35 and 37 rotate about a common axis disposed eccentrically
of the watch face along the position of the hour hand at 6 o'clock. The wheel 35 carries
an alarm minute hand 38 and the wheel 37 carries an alarm hand 39.
[0064] When the second stem 23 is in the first state to select a timer set or alarm mode,
the rotor 33 is rotated through 180° on an electrical signal from the CMOS-IC 20 by
pushing the button 26 once to close the switch connected to terminal C. The alarm
minute hand 38 turns through 6° representing 1 minute, and the alarm hour hand 39
turns through 0.5°. Thus the alarm time can be set at minute intervals up to 12 hours.
For this, if the button 26 is pressed continuously, the alarm minute hand 38 and the
alarm hour hand 39 rotate rapidly, thus setting the alarm time in a short time. When
the set alarm time and the ordinary time coincide, an alarm rings.
[0065] When the second stem 23 is placed in the zero state, an alarm off mode is selected,
and the alarm minute hand 38 and the alarm hour hand 39 indicate ordinary time. In
this case, the rotor 33 is rotated in steps of 180° at every minute on an electrical
signal from CMOS-IC 20.
[0066] The CMOS-IC 20 is connected with other electric elements as shown in the circuit
diagram of Figure 16. These other elements include buzzer driving elements consisting
of a boosting coil 55, a mini-mold, or small sized surface coupling, transistor 56
with protective diode and a piezo-electric buzzer 64 applied to a back cover of the
watch case. A 1uF chip capacitor 57 suppresses voltage fluctuations of the constant
voltage circuit 200. A micro tuning fork type crystal oscillator 58 is the source
for the oscillator circuit 206 through terminals
Xin and
Xout. A three position switch 46a can be closed on terminal RA1 or on terminal RA2 or
be open. A similar three position switch 59a can be closed on terminal RB1 or on terminal
RB2 or be open.
[0067] The buttons 24, 25 and 26 are spring-biased and can only close their switches when
pushed. The switch 46a is on a yoke 46 engaged with the first stem 22, so as to close
with terminal RA1 in a first state of the first stem 22, to close with terminal RA2
in a second state and to open normally. Likewise, the switch 59a is on a lever 59
engaged with the second stem 23, so as to close with terminal RB1 in a first state
of the second stem 23, to close with terminal RB2 in a second state, and to open normally.
[0068] The watch (Figure 17) has a case 40. On the watch face 41 are indicia 42 for ordinary
second time, indicia 43 for a chronograph minute and timer elapsed time second indication,
and indicia 44 for an alarm set time indication.
[0069] Ordinary time is indicated by the small second hand 14 stepping at every second,
whilst the minute hand 11 and the hour hand 12 rotate more slowly. For correcting
the time, the first stem 22 is pulled out to the second state. The first stem 22 engages
a lever 45 and yoke 46 to move a setting lever 47 which engages and stops the fourth
wheel 6. The first stem 22 is then rotated and through a clutch wheel 48 rotates a
setting pinion 50 in either direction. The pinion 50 (Figure 11) is engaged with the
gear 9a of the intermediate wheel 9. Rotation of the wheel 9 is transferred to the
minute wheel 8 and the hour wheel 10. The gear 8a of the minute wheel 8 is coupled
to the wheel 8 and pinion 8b with constant sliding torque, so that relative rotation
can occur under the torque applied manually through the stem 22 because the stopping
of the fourth wheel 6 also stops the third wheel 7 and gear 8a. The rotor 4 also stops
and the second wheel 13 (Figure 12) also stops. When the minute and hour hands 11
and 12 have been set to the desired time, the stem 22 is returned from its second
state to its normal position and the rotor 4 re-starts rotation to drive the hands
11, 12 and 13.
[0070] If a 1 Hz interrupt (Figure 18 (a)) is input, it is first determined whether or not
the switch 46a is connected to terminal RA2. If not, then a forward correction drive
of the step motor A is set on the motor drive system controlling circuit 219 (Figure
3) and a drive number 1 is set on a motor clock controlling circuit 226. If the switch
46a is connected to the terminal RA2, a time corrected state (Figure 18 (a)), the
motor drive is stopped, and divider circuits 208 and 209 are re-set instantaneously
so as to drive the motor one second later at the point in time when the switch 46a
is turned off.
[0071] In the flow chart of the chronograph function (Figures 19 (a) and 19 (b)), CG is
used as an abbreviation for chronograph. When a switch input to the circuit 217 occurs,
it is first determined whether the second stem 23 is not in the first or second state,
so that the switch 59a is not on the terminal RB1 or RB2. If the switch 59a is not
on either terminal, then it is determined whether the switch input comes from pushing
the button 24 to connect to terminal A. If so, the data memory is read to determine
if
CGreset or
CGstop is stored therein. If so, then the CG circuit is started and
CGstart is written into the memory in place of
CGreset or
CGstop.
CGstart causes the CG second hand 21 to be driven five steps per second from the zero position
from which it starts. The number of seconds is counted in both the counter 2113 and
the counter 2114 and after 60 seconds, a carry causes the CG minute hand 31 to be
stepped to indicate the passage of one minute of time.
[0072] This continues until another switch input occurs and is found to be from the terminal
A due to a push on the button 24. It is first determined whether
CGstart has occurred and because
CGstart is written in the memory, the CG circuit is stopped and
CGstop is written into the memory in place of
CGstart. Thus the CG second hand 21 and the CG minute hand 31 are both stopped and the elapsed
time can be read off the watch face. If, whilst
CGstart is in the memory, a switch input is found not to be from terminal A, it is determined
whether it is from terminal B. If so, then it arises from a push on the button 25
and CG split is started and
CGsplit is written into the memory in place of
CGstart. This stops the rotation of the CG second hand 21 and the CG minute hand 31, but
continues the counting of the seconds passing in counter 2113. Thus a split time can
be read from the hands 21 and 31 off the watch face.
[0073] If a further push on button 25 occurs thereafter, and it is determined that
CGsplit is in the memory, then a calculation occurs as to the difference between the CG hand
position as it is recorded in counter 2114 and the CG hand position as it ought to
be as recorded in counter 2113. The difference in circuit 2115 causes the CG hands
to be driven quickly until it is eliminated when they continue to rotate at normal
forward speed. At the same time,
CGstart is re-written into the memory in place of
CGsplit.
[0074] If, after the button 24 has been pushed to stop the chronograph indication and
CGstop has been written into the memory, the button 25 is pushed, then after a determination
that
CGstart and
CGsplit are not in the memory and that
CGstop is in the memory, the difference between the hand position and the zero hand position
is calculated and the hands rapidly returned to the zero position as indicated in
the circuit 2116, whilst
CGreset is written into the memory in place of
CGstop.
[0075] If, after the button 25 has been pushed and
CGsplit written into the memory, the button 24 is pushed to close the switch upon terminal
A, then the hand is already stopped at the split time. The counting of seconds is
stopped and the accumulated value is retained in memory. If the button 25 is again
pushed to close the switch upon terminal A, counting is restarted, but the hand remains
stopped.
[0076] If the second stem 23 is moved to the first state, the switch 59a engages the terminal
RB1 and the flow chart of Figures 20 (a) and 20 (b) indicates the resultant steps
in the timer set mode. If a switch input to circuit 217 is detected, it is first determined
whether the terminal RB1 is connected. If so, it is determined whether the terminal
A is connected due to the button 24 being pushed. If so, it is determined whether
timerset or
timerstop is written in the memory. There is no need to write
timerset into memory, if it is determined that neither
timerstart nor
timerstop is written in memory, it is assumed that
timerset is so written. If so, the timer is started as described in relation to Figure 20
(b) and
timerstart is written into the memory. If in the previous deter mination, it is found that
timerstart is written in the memory, then the timer is stopped and
timerstop written in the memory. A further push on button 24 restarts the timer.
[0077] If in the initial determination, it is found that the button 25 has been pushed so
that the terminal B is connected, it is determined whether
timerset is written in the memory. If so, then this indicates that neither
timerstart nor
timerstop is written in the memory and that a timer operation is not in progress. Accordingly,
the timer set time is increased by one minute and this is indicated by clockwise stepping
of the CG second hand 21 by five steps representing 6° on the watch face 41. Repeated
pushing of the button 25 causes repeated increases and stepping until the CG second
hand 21 indicates the desired timer set time. The maximum time that can be set is
60 minutes. When the timer is started by pushing the button 24, the 1 Hz interrupt
signal with
timerstart written in the memory causes a decrease of one second in the time set each second
and the CG minute hand 31 is driven counter clockwise. Every minute, the CG minute
hand completes a full circle and the CG second hand 21 is stepped five steps counter
clockwise until only one minute remains. Then the CG minute hand 31 stops and the
CG second hand 21 is stepped five steps for each second. At each decrease of timer
time by one second, it is determined (Figure 20 (b)) whether the time remaining is
one to three seconds. If not, then it is determined whether no time remains. If not,
then it is determined whether the time remaining is one minute or more. If so, the
CG minute hand 31 is stepped by one second counter clockwise and it is determined
if the timer second = 0. If so, then the CG second hand 21 is stepped counter clockwise
by five steps. If the remaining time is found to be one to three seconds, a command
is issued to the sound generator to output a notice sound. If the remaining time is
zero, a command is issued to the sound generator to output a time-is-up sound. If
the remaining time is less than one minute, the CG second hand 21 is stepped counter
clockwise by five steps. If a time of one minute only is set, the elapse of time is
only indicated by counter clockwise movement of the CG second hand 21. Otherwise,
time elapsed is shown by both hands 21 and 31 until only one minute remains. It will
be appreciated that when the remaining time is zero, the CG minute hand 31 is already
in a zero position and the CG second hand 21 is stepped through five steps back to
the zero position.
[0078] A flow chart of the alarm function is illustrated in Figures 21 (a), 21 (b) and 21
(c). When a switch output is received in circuit 217, it is first determined whether
the switch 59a is on terminal RB1 due to the second stem 23 being in the first state.
If so, it is determined whether the button 25 has been pushed to close on the terminal
C. If so, the alarm minute hand 38 is stepped forward by one minute and the alarm
hour hand 39 by a corresponding amount. This can be repeated until the desired alarm
time is set or the button can be kept pushed in, in which case both hands 38 and 39
are rotated quickly to enable the alarm time to be set in a short time. At the same
time, the alarm set time is written into the memory. When a 1 Hz interrupt is received,
and the second stem has not been moved into the second state, the alarm current time
is increased by one second. It is then determined if the time has increased by one
minute, as represented by "figure up?". If so, and it is found that the second stem
is still in the first state, the alarm current time and the alarm set time are compared.
If identity is found, then a command is issued to the sound generator to output the
notice sound. If the second stem is not in the first state, it must be in the zero
or normal position and the alarm minute hand is advanced by one step to keep pace
with current time. Thereafter, the alarm minute and hour hands 38 and 39 will display
the current time. However, if there is a need to correct the position of the hands,
the second stem is moved to the second state and rotated to move the hands through
the clutch wheel 49 and setting wheel 51 (Figure 15).
[0079] If a switch output is detected (Figure 21 (c)), it is determined whether the second
stem has been moved from the second state to release the terminal RB2 in operation
2301. If not, the condition of the mode switch in relation to terminal RB1 is checked.
In operation 2302, it is determined whether the terminal RB1 has been engaged. If
so, the alarm function is changed to indicate the alarm set time. This is effected
by calculating the difference between the alarm set time and the alarm current time
in operation 2303. A quick driving traverse of the alarm minute and hour hands is
effected in operation 2304 until the displayed time coincides with the calculated
value and thus the alarm set time. If not, it is determined whether the terminal RB1
has been released in operation 2305. If so, the alarm function is changed to indicate
current time. This is effected in operation 2306 by calculating the difference between
the alarm current time and the alarm set time. A quick driving traverse of the alarm
minute and hour hands is effected in operation 2304 until the displayed time coincides
with the calculated value and thus the alarm current time.
[0080] Various motor driving methods are illustrated in Figures 22 (a), 22 (b) and 22 (c).
When motor movement is called for (Figure 22 (a)), it is first determined if the pulses
required are for reverse I or forward I drives. If so, then the reference clock is
set to 64 Hz, whereas if not, it is set to 128 Hz. The selection of the correct motor
to drive the hands requiring movement is then made and the number of pulses set in
the motor pulse register 2261 (Figure 9). If the drive called for is reverse I or
forward I, then the necessary pulses are issued to the selected motor until the contents
of the up counter 2262 counting incoming pulses is found to be equal to the contents
of the register 2261 by the circuit 2263. The clock signals
Cdrv arrive at 64 Hz.
[0081] If a quick traverse drive is called for, then the reference clock having been set
on 128 Hz, the motor pulse register 2261 is set at 15, if there are 15 or more pulses
to be issued, and forward II drive is set, 15 is then deducted from the number of
output pulses.
[0082] If a control interrupt occurs, it is first determined if it is an interrupt of a
quick traverse motor. If so, then it is determined whether the number of output pulses
is less than 14. If so, then that number of pulses is set into register 2261 by the
switch 2271. If not, then 15 is deducted from the number of output pulses.
[0083] In the second embodiment of a multi-functional electronic watch according to the
invention (Figure 23), only three step motors are used to achieve multi-functional
operation. Thus from the watch illustrated in Figure 10, there are omitted the D motor
32, the alarm intermediate wheel 34, the alarm minute wheel 35, the third alarm wheel
36, the alarm hour wheel 37, the second stem 23, the clutch wheel 49, the setting
wheel 51, the switch button 26, and the lever 59, so that the alarm and timer functions
are removed. Thus, the hands 38 and 39, and the face indicia 44 are not needed and
are removed. In the second embodiment, the wheel 13 is disposed, not along the line
of the hour hand in the 9 o'clock position, but eccentrically of the watch along the
line of the hour hand in the 6 o'clock position. The face indicia 42 (Figure 25) are
similarly displaced. Instead of being driven from the wheel 5 (Figure 12), the wheel
13 (Figure 24) is driven through an intermediate gear wheel 60 from the wheel 6 driven
by the wheel 5 from the rotor 4. The gear 6a of the wheel 6 engages with a gear 60a
on the intermediate gear wheel 60, and the gear 60a engages with the gear 13a on the
wheel 13 carrying the hand 14. The reduction ratio between the rotor 4 and the wheel
13 is 1/30, and the second hand 14 fitted on the nose of the wheel 13 is stepped every
second, thus indicating seconds of ordinary time.
[0084] The watch also has a chronograph function performed through step motor B 15 and step
motor C 27 as in the case of the first embodiment. Further description is superfluous.
As shown in Figure 25, only the first stem 22, switch button 24 and switch 25 are
provided. Hour and minute indications of the ordinary time, chronograph indication
and the operating method are the same as the first embodiment.
[0085] In the third embodiment of multi-functional electronic watch according to the invention
(Figure 26), only two step motors are used, and the multi-functional electronic watch
provides an ordinary time indication and an alarm function. Thus from the watch illustrated
in Figure 10, there are omitted the step motor 15 and the stem motor 27, together
with related gear trains and hands, so that the chronograph and timer functions are
taken away. Accordingly, the CG first intermediate wheel 17, the CG second intermediate
wheel 18, the CG wheel 19, the CG minute intermediate wheel 29 and the CG minute wheel
30 are not required. In addition, the second wheel 13 is replaced by a central second
wheel 62 (Figure 27) disposed in place of the CG wheel 19, thereby indicating seconds
of ordinary time in a central position of the watch. Thus, the gear 6a of the wheel
6 engages a gear 61a of an intermediate wheel 61. The gear 61a also engages a gear
62a of the central second wheel 62. The gear train between the wheel 6 and the rotor
4 is similar to that of Figure 11. The reduction ratio between the rotor 4 and the
second wheel 62 is 1/30, and a central second hand 63 is fitted on a nose of the wheel
62. Each second, the hand 63 is stepped over the face 41 of the watch to indicate
seconds of ordinary time.
[0086] Hour and minute indications of ordinary time and indication of alarm time set by
the step motor 32 are effected as in the case of the first embodiment, so that further
description is superfluous.
[0087] As seen in Figure 28, ordinary time is indicated by the co-axial second hand 63,
minute hand 11 and hour hand 12. The method for correcting the time is similar to
that of the first embodiment, by means of the first stem 22.
[0088] As no chronograph and timer functions are provided, the switch operating button 26
is the only one needed.
[0089] The method for indicating alarm set time and the operation thereof are the same as
for the first embodiment.
[0090] Other than the embodiments described above, various changes within the scope of the
invention may be made. Thus, a watch with only a single motor, or a 12 hour position
small watch are conceivable. By use of the invention, these may be realised easily
by a slight adjustment in number or re-arrangement of parts.
[0091] In the embodiments of the invention described above, an ordinary time and additional
functions may be indicated easily at arbitrary positions of the watch by selecting
the number and disposition of additional function indicating step motors, and the
number and disposition of gear trains. Thus, a single movement is effective in realising
a multi-functional electronic watch of various specifications. Further, as almost
all the main parts including base plate and step motor can be used in common, an increase
in die cost due to a change in specification and also an increase in cost due to a
change in part design, such as would be incurred with prior art watches, can be avoided.
Different specifications can be realised simply by re-writing the software of the
micro-computer, so that standardisation on a common IC chip is also realisable. The
various faces of watch needed may be easily contrived, thus coping with diverse consumers'
needs.
[0092] Other advantages of the described embodiments of the invention follow. As the small
alarm face and hands are independent of and separate from the basic watch face and
hands, alarm time and ordinary time are more definitely distinguishable, so that the
chances of erroneous setting of alarm time will be reduced. The small alarm hands
can be used for selecting the alarm time or the ordinary time, and can be changed
by the same stem, so that the function is readily combined with a basic watch to use
as a composite watch, which is serviceable particularly when travelling abroad. Alarm
time and ordinary time of the small alarm hands are corrected by a button and a stem,
so that the correcting operation is more definite, and erroneous operation is consequently
less likely. As the chronograph second hand is disposed centrally of the watch, the
time can be read easily, thus enhancing time keeping precision. The timer indication
is given by separate minute and second hands driven counter clockwise, which is effective
in discriminating from the chronograph indication, thus facilitating reading of the
timer residual time.
[0093] The chronograph second hand disposed centrally of the watch is driven every second
for the last minute of the timer time, thus ensuring a more serviceable timer function.
Ordinary time indicated by the small alarm hands is corrected by turning the second
stem, and ordinary time shown by the basic watch hands is corrected by turning the
first stem. As the first stem is intended for exclusive use on the time keeping of
the basic watch, and the second stem is intended for both mode switching and correction,
errors are more easily avoided by the simple operation needed. The two stems are disposed
at positions away from the small face indicia over which the small hands pass, so
that such a multi-functional watch can be thinner.