JPH0415918B2 - - Google Patents

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to all electronic devices having a date display function, such as personal computers, OA related machines, ECRs, and clocks, and in particular, to automatic determination of leap years. The present invention relates to a date display device having functions.

[Conventional technology]

Conventionally, in this type of automatic date device, a 2-bit leap year counter was installed that was completely independent of the "year" counter, and a "month" counter was installed to detect leap years.
A carry signal from the counter was supplied to the "year" counter and also to this leap year counter, and a leap year was determined based on the contents of the leap year counter.

[Problem that the invention seeks to solve]

In the conventional leap year determination method described above, the contents of the leap year determination counter and the contents of the "year" counter are completely independent. The leap year detection signal from the determination counter will be generated in a year different from the true leap year.
Therefore, the leap year determination counter also had to be modified, making the operation and circuit configuration complicated.

[Means for solving problems]

The electronic automatic date device according to the present invention includes a year counter, means for generating a carry signal to the year counter, a leap year judgment counter to which the carry signal is further supplied, and a counter responsive to a year counter adjustment control signal. means for setting data related to the data of the lower two bits of the first year counter of the year counter in a leap year determination counter; and means for determining the value of the content of the leap year determination counter as a leap year. have

According to the present invention, the leap year determination counter is
It also has a preset function that allows the setting data to be preset externally.

According to a preferred embodiment of the present invention, the data setting means for the leap year determination counter is configured to set data in the least significant bit of the first year digit and the next bit if the 10th digit of the year counter is an even number. When the 10th digit is an odd number, the data of the least significant bit of the 1st year digit and the complement data of the next bit are set in the leap year setting counter.

〔Example〕

Next, the present invention will be explained with reference to the drawings.

FIG. 1 is a block diagram showing one embodiment of the present invention. In FIG. 1, a control unit 10 controls a clock function unit and transmits the data to a display 1.
1 and various control devices 12. Furthermore, the control section 10 also has a function of aggregating data from various control devices 12 based on the contents of the clock function section.

The clock function section includes an oscillation section 9, a frequency dividing stage 8, a minute counter 7, an hour counter 6, a day counter 5, a month counter 4, a year counter 3, a counter setting circuit 2 for leap year determination, and a counter 1 for leap year determination. However, depending on the application, it is also possible to configure it with only year, month, and day counters.

FIG. 2 shows a more detailed circuit diagram of the leap year determination part. Year counter 3 is year 1st place counter 13
and year 10th place counter 14, these are
Consists of BCD code. Year 1st place counter 13 is Y ₀ , Y ₁ , Y ₂ , Y ₃ , year from the least significant bit.
10th place counter 14 is 10Y ₀ from the lowest bit,
10Y ₁ , 10Y ₂ , and 10Y ₃ respectively.
The year 1st place counter 13 is incremented by the carry signal 18 to the year, the year 10th place counter 14 is incremented by the signal from the year 1st place counter 13, and each bit of each counter 13 and 14 is incremented.
Y ₀ , Y ₁ , Y ₂ , Y ₃ and 10Y ₀ , 10Y ₁ , 10Y ₂ ,
10Y ₃ will change accordingly. Moreover, the year 10th place counter 14 and the year 1st place counter 13 receive correction data through terminals 10X ₀ to 10X ₃ and X ₀ , respectively.
~ with x ₃ . The correction data is in the control section 1.
0 and is input to each counter 13, 14 by the year digit correction input 16 supplied to each counter 13, 14 from the control unit 10.

Leap year determination counter 1 consists of a 2-bit binary counter, starting from the lower bit C ₀
and is familiar with C ₁ . The leap year determination counter 1 is incremented by the carry signal 18 to the year.

A year digit correction signal 16 is further supplied to the leap year counter 1. Counter 1 takes in the data supplied to its set input terminals XC ₀ and XC ₁ when signal 16 is present. A setting circuit 2 generates data to terminals XC ₀ and XC ₁ .

The setting circuit 2 includes an inverter 20 that receives the data of the least significant bit _10Y0 of the year 10th place counter 14;
The same data controls whether it is activated or not.
The gate 21 receives the data of the second least significant bit of the counter 13, and the inverter 22 receives the data of the second least significant bit of the counter 13, the activation of which is controlled by the output of the inverter 20. The outputs of the gate 21 and the inverter 22 are commonly connected and supplied to the set input terminal _XC1 of the counter 1. The least significant bit _Y0 of the year 1 counter 13 is supplied to the set input terminal _XC0 of the counter 1. Therefore, the circuit 2 supplies the data related to the data of the lower two bits of the year 1st place counter 13 to the counter 1 according to the state of the least significant bit ^10Y0 of the year 10th place counter 14. receives the data by applying the year digit correction signal 16. When bit 10Y ₀ is 0,
That is, when the year 10th counter 14 is an even number, the gate 21 is activated and the inverter 22 is inactivated. Therefore, the values of bits _Y1 and _Y0 of the first counter 13 are the values of the leap year determination counter 1.
will be set as is. On the other hand, when bit _10Y0 is 1, that is, when year 10th place counter 14 is an odd number,
Since the gate 21 is inactive and the inverter 22 is activated, the complement data of bit _Y1 and the data of bit _Y0 are set in the leap year determination counter 1. Thus, data corresponding to the correction data to the year counters 13 and 14 is set in the leap year determination counter 1.

The C ₀ and C ₁ bit outputs of the leap year setting counter 1 are supplied to an OR circuit 30 . OR circuit 30
detects that the contents of the counter 1 are in a specific state, in this example "00", and generates a leap year determination output 15. For example, if the content of the year counter is "1985"
, the year 10th place counter 14 is an even number, so the leap year determination counter 1 will be “01”.
The value of is set. When the carry signal 18 is supplied three times, that is, the content of the year counter becomes "1988".
In this case, the OR circuit 30 generates a low level judgment output 15. 1988 is a leap year. When the content of the year counter is corrected to "1990", the value of "10" is set in the leap year determination counter 1. Therefore, in 1992, two years after the leap year, the output of the OR circuit 30 becomes a low level as a leap year detection output signal. When this leap year determination output 15 is output, it is set as February 29th by the next day of February 28th, and when it is not outputted, it is March 1st.
day. This operation is performed by the control unit 10 for the day counter 5 and month counter 4 in FIG.

By the above operation, when the year name of the "Western calendar" is set (corrected) in the year counter, a leap year can be automatically determined according to the Western calendar. However, it is not possible to determine whether it is a leap year every 100 years, but the 10th and 1st
If the number is between 01 and 99, we can handle it. Also, since 2000 in the Western calendar is a leap year, leap years can be determined without adjustment until 2099 in the Western calendar.

The leap year determination counter 1 further has preset input terminals PC ₀ and PC ₁ , and in response to the preset signal 17, the counter 1 takes in the preset input. Preset input and preset signal 17 are generated from control section 10. If the contents of year counters 13 and 14 are set in Western calendar, leap years are automatically detected thereafter by supplying data based on bits Y ₀ and Y ₁ of the year 1 counter to counter 1 as described above. be done. However, if the contents of the year counter are set to another era, such as "Showa", the bit
If data based on Y ₀ and Y ₁ is set in counter 1, the year in which the leap year detection output occurs will be different from a true leap year. In such a case, the controller section 10 outputs the preset signal 17.
is supplied to the counter 1, and a preset input to be set in the counter 1 is supplied to the counter 1. For example, in the year counters 13 and 14, “Showa 60
When the year is set, the control section applies data of "01" to the preset input terminals PC ₀ and CP ₁ of the counter 1, respectively. As a result, three years later in 1988, the OR gate 30 sets the judgment output 15 to a low level. 1988 is a leap year.

In this way, in the circuit shown in Figure 2, "Nishireki"
Even if you correct the year counter in ``Showa'' or ``Showa'', subsequent leap year detection will be performed automatically.

In addition, in the configuration shown in Figure 2, the first year and
Create correction data for about 10 years and change correction signal 1.
6, the 1st year and 10th year counters 13 and 14
However, it is also possible to correct the counters 13 and 14 by serially supplying the correction data to the counters 13 and/or 14 using a fast-forward signal for correction, as has been done in the past. good. At this time, the time when the counter 1 takes in the data from the setting circuit 2 may be the time when the correction is completed. It is also possible to provide a switch circuit that receives the data from the setting circuit 2 and the preset input, and to select one of them and supply it to the counter 1 depending on the presence or absence of the preset signal 17.

FIG. 3 shows another embodiment of the invention, in which the same functional parts as in FIG. 2 are designated by the same numbers. In Figure 3, the least significant bit of year 1 counter 13 is
The _Y0 counter is shared with the least significant bit _C0 counter of the leap year determination counter in Figure 2,
Therefore, the carry signal from the least significant bit _Y0 counter is supplied to the 1-bit counter 40, which is a flip-flop. The OR circuit receives the output _C1 of the counter 40 and the least significant bit output _Y0 and generates a leap year determination output. Setting circuit 2 is
Depending on whether the content of the 10th place counter is an even number or an odd number, it is controlled whether the output _Y1 of the lower two bits to be supplied to the counter 40 is a complement number.

According to this embodiment, leap year detection is automatically performed after correcting the contents of the year counter with the "Western calendar" using a smaller number of elements than the one in FIG.

〔Effect of the invention〕

As explained above, in the present invention, when setting the year digit,
By setting a value in the leap year determination counter through the leap year determination counter setting circuit, it becomes possible to automatically determine a leap year according to the western calendar. Furthermore, leap year determination counter 1 has the following information:
It is also possible to set other values independently of the year digit setting, and it is possible to support eras other than Western history.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing one embodiment of the present invention, FIG. 2 is a circuit diagram showing a specific configuration, and FIG. 3 is a circuit diagram showing another specific configuration.

Claims (1)

[Scope of Claims] A one-year counter, a first means for generating a carry signal to the year counter, a leap year determination counter for counting the carry signal, and a first means for generating a carry signal to the year counter; If the 10th digit of the year in the counter is an even number, the data of the least significant bit of the 1st digit of the year in the year counter and the data of the next bit of the least significant bit are converted to the least significant bit of the leap year determination counter. If the 10th digit of the year is an odd number, the data of the least significant bit of the 1st digit of the year and the complement data of the next bit of the least significant bit are set to the most significant bit of the leap year determination counter. A timepiece device comprising: second means for respectively setting the lower bit and the next bit; and third means for detecting the contents of the leap year determination counter and generating a leap year detection signal. 2. Claim 1, further comprising a fourth means for setting setting data different from the setting data from the second means to the leap year determination counter when correcting the contents of the year counter. Clock device as described in section. 3. A year counter, a first means for supplying a first carry signal to the year counter, and a second carry signal corresponding to the data of the least significant bit of the first digit of the year in the year counter. When modifying the contents of the leap year determination counter to be counted and the year counter, if the 10th digit of the year in the year counter is an even number, the year 1 is
If the 10th digit of the year counter is an odd number, the data of the next bit after the least significant bit of the year counter is
a second means for setting complement data of the next bit of the least significant bit of the digit in the leap year determination counter; and detecting the contents of the least significant bit of the first digit of the year and the contents of the leap year determination counter. and third means for generating a leap year determination output.