JPH0236915B2 - SUNUUZUTSUKI DENSHITOKEI - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention relates to an electronic timepiece that has two types of alarms: an alarm based on an acoustic signal and an alarm that controls an external device, and is also equipped with a snooze function.

(b) Prior Art Conventionally, in electronic watches equipped with a snooze function, when it is detected that a preset time has arrived, a flip-flop is set based on the coincidence detection output, and the output of this flip-flop is used to generate an alarm sound. Output a signal to generate.
When the snooze switch is operated during the alarm period, a flip-flop is set that stores the snooze request, and a timer circuit that measures the snooze time is started. The output of the flip-flop for snooze prohibits the output of the signal for generating the alarm sound, and the timer circuit generates the alarm sound by resetting the flip-flop for snooze when the output when a predetermined time has been counted. Lift the ban on traffic lights. In this manner, the alarm sound generated when the predetermined alarm time has arrived is stopped for a certain period of time by operating the snooze switch, and then resumed. This technique is disclosed in Japanese Patent Application Laid-Open No. 54-4170.

(C) Problems to be Solved by the Invention However, when adding a snooze function to an electronic watch that is equipped not only with a sound means as an alarm but also with an external device control signal that controls an external device such as a radio, It must be selected whether it is the sound means or the external device that is to be stopped by operating the snooze switch. If only one of them is controlled, or if both are controlled at the same time, the function will be simple and the product will be unattractive.

(d) Means for solving the problems The present invention has been made in view of the above-mentioned points, and provides an alarm time coincidence detection signal, or
An alarm stop counter that starts operating in response to a snooze request signal generated by operating a snooze switch and outputs a first signal indicating elapsed time _t1 and a second signal indicating elapsed time _t2 , and the snooze request signal. a snooze circuit that changes the state of its output depending on the output of an alarm drive signal for generating a controlled alarm sound; a gate circuit that controls the alarm drive signal based on the output of the snooze circuit and the first signal; The snooze function is different with respect to time t ₁ and time t ₂ by comprising a control circuit having a gate circuit that controls an external device control signal based on the output of the snooze circuit and the first signal and the second signal. .

(E) Effect According to the above-mentioned means, for example, a radio etc. is turned on by an external device control signal from the alarm time until t ₁ hour, and after t ₁ hour, not only the radio but also the alarm sound, such as a buzzer, is turned on. In the alarm pattern, if the snooze switch is operated before t ₁ hour, the radio will be stopped for t ₁ hour, and if the snooze switch is operated once after t ₁ hour, the radio will remain on and only the buzzer will be turned off. If the snooze switch is operated _once again before the buzzer sounds again, the radio will stop, and the radio will turn on again after ₁ hour and the buzzer will turn on again after ₂ hours. be.

(F) Embodiment FIG. 1 is a block diagram showing an embodiment of the present invention, in which 1 is a current time counter, 2 is an alarm time storage circuit, 3 is a coincidence detection circuit, 4 is a flip-flop (FF) for alarm storage, 5 is a control circuit, 6 is a snooze circuit, and 7 is an alarm stop counter. The current time counter 1 counts the minute signal C ₈ that is output once every minute from a second counter (not shown).
It measures minutes and hours, and the timed hours and minutes are displayed on a display device (not shown). In the alarm time storage circuit 2, the time at which an alarm should be generated, that is, the hour and minute, is preset by an external operation switch, and the alarm time is displayed on a display device as necessary. The general detection circuit 3 compares the output of the current time counter 1 and the output of the alarm time storage circuit 2, and outputs a coincidence detection signal DE when they match, that is, when the current time and the alarm time match. The alarm storage FF4 is a flip-flop that is set by the coincidence detection signal DE and stores that the alarm time has arrived.
It is reset by the signal _T59 output from the alarm stop counter 7 after 59 minutes. The output Q of the alarm memory FF4 is applied to the control circuit 5, and the control circuit 5 outputs a radio control signal RADIO, which is an external device control signal, and a buzzer drive signal BUZ, which is an alarm drive signal.
It controls the output of . The control circuit 5 receives the output of the snooze circuit 6, the first signal T10 which becomes "1" for a time _t1 ( _t1 = 10 minutes) from the start of operation of the alarm stop counter ₇ , and the time _t2 ( _t2) from the start of operation. =20 minutes)
The output pattern of the radio control signal RADIO and the buzzer drive signal BUZ is controlled based on the second signal _T20 which becomes "1" during the period, and the output of the snooze circuit 6 and the signals _T10 and _T20 are applied to the selection. AND
Gates 8, 9, 10, NAND gate 11 and
NOR gate 12, NAND gate 11 and NOR
The output of gate 12 is applied to the FF for alarm storage.
AND gates 13 and 14 to which the output Q of 4 is applied
and AND gate 1 to which the output of AND gate 14 and the buzzer drive frequency signal BUZTONE are applied.
The output of the AND gate 13 is the radio control signal RADIO, and the output of the AND gate 15 is the buzzer drive signal BUZ. The snooze circuit 6 is controlled by a snooze request signal SNOOZ generated when a snooze switch (not shown) is operated, and determines whether or not the buzzer drive signal BUZ is output, that is, the output of the AND gate 14. The memory state changes depending on whether it is "1" or "0", and the output of the AND gate 14 is applied to the latch input L via the inverter 16, and the snooze request signal SNOOZ is applied to the clock terminal ψ of the latch. circuit 17, AND gates 18 and 19 to which the snooze request signal SNOOZ to which the output Q of the latch circuit 17 is applied, and the AND gate 18
The output of the AND gate 19 is applied to the set terminal S, and the output of the AND gate 19 and the coincidence detection signal DE are applied to the reset terminal R.
The output Q of the FF 21 is applied to the AND gates 8 and 10 and the NAND gate 11 of the control circuit 5.
The signal inverted by the inverter 22 is AND
applied to gate 9. Alarm stop counter 7
is created by counting the minute signal _Cs from when the alarm times match until the alarm is stopped, and when the match detection signal DE is applied via the OR gate 23, 59 minutes is calculated. It is preset and subtraction counting starts. After 59 minutes, the signal _T59 is output to reset the alarm storage FF4, and the minute signal _Cs is inhibited by the OR gate 24 to stop the counting operation. Also, the time t ₁ (10
The signal T ₁₀ which becomes “1” during
The signal T ₂₀ that is applied to the AND gates 9 and 10 and remains “1” for a time t ₂ (20 minutes) from the start of operation is an AND gate.
Applied to gate 8. Further, the alarm stop counter 7 is again preset to 59 minutes and starts operating in response to the snooze request signal SNOOZ even if it is in operation.

Figure 2 shows the operation of the circuit configured as shown in Figure 1.
This will be explained with reference to FIGS. 3, 4, and 5.
In the case of Fig. 2, the alarm time memory circuit 2
Alarm time set to and current time counter 1
When the times match, the coincidence detection circuit 3 outputs a coincidence detection signal DE. In response to the coincidence detection signal DE, the alarm stop counter 7 is preset to 59 minutes and starts its operation, and the alarm storage FF 4 is also set, and its output Q becomes "1". At this time, the signals _T10 and _T20 applied from the alarm stop counter 7 to the control circuit 5 both become "1",
In addition, FF21 of the snooze circuit 6 is a coincidence detection signal.
Since it is reset by DE, its output Q is "0". Therefore, in the control circuit 5,
The output of the AND gate 10 to which the output Q “0” of the FF 21 is applied is “0”, and the NAND gate 11
Since both inputs are “0”, its output is “1”
becomes. Therefore, AND at the same time as alarm matching
Output of gate 13, i.e. radio control signal
RADIO turns on. On the other hand, the output of the inverter 22 that inverts the output Q of the FF 21 is "1",
In addition, since the signal T ₁₀ is also “1”, the AND gate 9
The output of the NOR gate 12 becomes "1", and the output of the NOR gate 12 becomes "0". Therefore, the output of the AND gate 14 becomes "0", inhibiting the buzzer drive signal BUZ. Then, 10 minutes later, when the signal _T10 becomes "0", the output of AND gate 9 becomes "0", and the NOR
Since the output of the gate 12 becomes "1", the output of the AND gate 14 becomes "1" and the buzzer drive signal
BUZ is output. Furthermore, after 20 minutes, T ₂₀ becomes "0", and this signal T ₂₀ causes the radio control signal to be
RADIO and buzzer drive signal BUZ do not change.
59 times since alarm stop counter 7 started operating
When the signal _T59 becomes "1" after a minute, the operation of the alarm stop counter 7 stops, and the alarm memory FF4
is reset, AND gates 13 and 14 output the radio control signal RADIO and the buzzer drive signal BUZ.
Stop outputting. In this way, in the case of the operation shown in Figure 2, after an alarm match, only the radio is turned on for 10 minutes, the buzzer is also turned on after 10 minutes, and both are turned off after 59 minutes. be.

Figure 3 shows a case where the snooze switch is operated within 10 minutes after an alarm match; similar to Figure 2, if the snooze switch is operated when only the radio is on due to an alarm match, a snooze request is issued. Due to the “1” pulse of the signal SNOOZ,
The alarm stop counter 7 is again preset to 59 minutes and starts operating from the initial state. Also, at this time, since the output of the AND gate 14 is "0", the output "1" of the inverter 16 is applied to the input L of the latch circuit 17, and the output Q of the latch circuit 17 is "1" and "0". ”. Therefore, the pulse of the snooze request signal SNOOZ is applied to the AND gate 18.
Since it is output via , FF21 is set,
Its output Q becomes "1". Then the signal T ₁₀ =
Since the output of the AND gate 10 to which "1" is applied becomes "1", the output of the NAND gate 11 becomes "0", and the AND gate 13 receives the radio control signal.
Disable RADIO output. Then, 10 minutes after the radio is turned off by snooze, the signal is
_T10 becomes "0". Then, the output of the AND gate 10 becomes "0" and the output of the NAND gate 11 becomes "1", so the AND gate 13 outputs the radio control signal RADIO again. Furthermore, when the signal T ₂₀ becomes "0" after 20 minutes, the AND gate 8
Since the output of the AND gate 9 is "0" and the output of the AND gate 9 is also "0", the output of the NOR gate 12 is "1".
4 outputs the buzzer drive signal BUZ. and
When the signal _T59 becomes "1" after 59 minutes, the operation of the alarm stop counter 7 is stopped and the alarm storage FF4 is reset, so that the radio and buzzer are turned off. In this way, if you operate the snooze switch within 10 minutes of the alarm matching, the radio will be turned off for 10 minutes to snooze.

FIG. 4 shows a case where the snooze switch is operated 10 minutes after the alarm matches. As shown in Figure 2, after 10 minutes the radio control signal
Both RADIO and buzzer drive signal BUZ are being output. Therefore, when the snooze switch is operated, the snooze request signal SNOOZ becomes "1".
However, at this time, the output "0" of the inverter 16 is applied to the input L of the latch circuit 17 due to the output "1" of the AND gate 14, and the output Q of the latch circuit 17 is " 0”, is “1”
It is becoming. Therefore, FF 21 remains in the reset state. Meanwhile, snooze request signal SNOOZ
Since the alarm stop counter 7 is preset to 59 minutes and starts operating from the initial state, the signal
_T10 becomes "1" again. When the signal _T10 becomes "1", the output of the AND gate 9 to which the output "1" of the inverter 22 is applied becomes "1",
The output of the NOR gate 12 becomes "0". As a result, the AND gate 14 stops outputting the buzzer drive signal BUZ. Then, 10 minutes after the snooze, the signal T ₁₀ becomes "0" again.
AND gate 9 output is “0”, NOR gate 12
Since the output of is “1”, the AND gate 14
outputs the buzzer drive signal BUZ. Furthermore, 59
When the signal _T59 becomes "1" after a minute has passed, the operation of the alarm stop counter 7 is stopped, the alarm storage FF4 is reset, and the radio and buzzer are turned off. In this way, by operating the snooze switch once while the radio and buzzer are on, only the buzzer will be turned off for 10 minutes.

FIG. 5 shows the case where the snooze switch is operated twice 10 minutes after the alarm matches. In this case, the first operation of the snooze switch is the same as the operation shown in FIG. 4, and only the buzzer stops. When the snooze switch is operated for the second time within 10 minutes after the buzzer stops, the counter 7 is preset to 59 minutes again from the alarm stop due to the "1" pulse of the snooze request signal SNOOZ. Start operation from the initial state. At this time,
Since the output of the AND gate 14 is "0", the output "1" of the inverter 16 is applied to the input L of the latch circuit 17, so the output Q of the latch circuit 17 is "1" and "0". It's summery. Therefore, by the pulse of the snooze request signal SNOOZ
FF21 is set and its output Q becomes "1". Then, the output of the AND gate 10 to which the signal T ₁₀ of "1" is applied becomes "1", and the output of the NAND gate 11 becomes "0", so the AND gate 13 receives the radio control signal RADIO. Prohibit output. Then, after 10 minutes, the signal
Since T ₁₀ becomes "0", the output of the AND gate 10 becomes "0", and the output of the NAND gate 11 becomes "1", so the AND gate 13 outputs the radio control signal RADIO again. Furthermore, after 20 minutes have passed, the signal T ₂₀ becomes "0", so the output of AND gate 8 becomes "0", and the output of NOR gate 12 becomes "1", so the output of AND gate 14 becomes "1". ,
This outputs the buzzer drive signal BUZ. In this way, by operating the snooze switch twice while both the radio and buzzer are on, both the radio and buzzer will turn off, and the radio will turn on after 10 minutes and the buzzer will turn on after 20 minutes, resulting in snooze. be. Note that the alarm stop counter 7 can also be used as a sleep timer counter that turns on the radio for a certain period of time.

(G) Effects of the Invention As described above, according to the present invention, in an electronic watch that has both a radio and a buzzer as alarm means, the order in which the alarms are generated is stepwise, and the snooze can also be performed in multiple patterns. Therefore, a functional and easy-to-use electronic clock is obtained, and
It also has the advantage of increasing product appeal.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing an embodiment of the invention, and FIGS. 2, 3, 4, and 5 are block diagrams showing an embodiment of the present invention.
FIG. 3 is a timing diagram showing the operation of the embodiment shown in the figure. Explanation of main figure numbers 1...Current time counter, 2
... Alarm time storage circuit, 3 ... Coincidence detection circuit, 4 ... FF for alarm storage, 5 ... Control circuit,
6...Snooze circuit, 7...Alarm stop counter.

Claims (1)

[Claims] 1. When a match between the current time and a preset alarm time is detected, an alarm drive signal or an external device control signal is output, and the alarm drive signal or external device control signal is output by operating a snooze switch. In an electronic watch with a snooze function that stops signal output for a certain period of time, a predetermined value is preset by a coincidence detection signal generated when the current time and alarm time match or a snooze request signal generated by operating a snooze switch, and the elapsed time is an alarm stop counter that outputs a first signal indicating the elapsed time t ₁ and a second signal indicating the elapsed time t ₂ ; and an alarm stop counter that is controlled by the snooze request signal and changes the output state depending on whether or not the alarm drive signal is output. a snooze circuit; a gate circuit that controls the external device control signal based on the output of the snooze circuit and the first signal;
and a control circuit having a gate circuit that controls the alarm drive signal based on the output of the snooze circuit and the first signal and the second signal, and the snooze function is configured for the times _t1 and _t2 . An electronic clock with a snooze feature that is different.