DE4304321A1 - Adjusting receiving time of radio clock with time output unit and receiver unit - receiving radio wave contg. time information using detector unit for determining time at which radio wave can be most effectively received by the receiver unit - Google Patents

Abstract

The method involves using a time correction unit (7) for the correction of the time given on the basis of the time information, contained in the radio wave, which is received at the time, determined by the detector unit (9). The method for adjusting the receiving time of a radio clock involves activation of a receiver unit (2) for receiving a radio wave contg. an item of time information, at each desired time cycle, or at a desired time. The reception conditions at the time point are established, at which the receiving unit is activated, and the time, at which the radio wave can be received most effectively within an entire day, is determined for the receiving time. ADVANTAGE - Automatically selects time point at which radio wave can be most effectively received. Receiving operation can be selected at this time. Receiving time can be adjusted and time output corrected.

Description

The invention relates to a radio clock, a method for a position of the reception time with a radio clock and a procedure to correct the time on a radio clock.

Radio waves are broadcast in the United States and Germany, over which time information is superimposed. The time information tion represents the day, hour and minute in the form of digi taler signals with a period of one second. Clocks, that receive these radio waves and use them for time correction are commercially available. In Japan now under the supervision of the Ministry of Post and Telecommunications were experimentally a standard wave with superimposed time information sent. This time information includes one Frame that is one minute long and contains data that the Day, hour and minute in the form of digital signals present, whereby one bit corresponds to one second. In Japan, the authorities concerned are planning regular Transmission of time information about radio waves in the near Introduce future. There is therefore an increasing need for clocks that use the time infor the time Correct the transmission radio wave. Conventional Radio clocks are designed so that they the process of Zeitsig reception and time correction to minimize the Electricity consumption with a set period or only to execute a certain time.

In the conventional watches described above, time is for receiving the time signal regardless of the reception conditions specified. As a result, the case may arise that the time information due to a weak field strength  not received satisfactorily when receiving the radio waves can be gen. That means performance is undesirable for a useless reception process is consumed.

The object of the present invention is to provide a radio clock that automatically selects a time at which a radio wave can be received effectively and the Reception process at the time selected in this way. The object of the invention is also a method for a position of the reception time and a procedure for time correction to create the radio clock.

This object is achieved according to the invention by a radio clock Claim 1, a method for setting the reception time according to claims 2 and 5 or a method for time correction according to claims 3, 4 and 6 ge solves.

Exemplary embodiments of the invention are described below the drawings explained in more detail. Show it:

Fig. 1 is a block diagram of a first embodiment of the present invention,

FIG. 2 is a flowchart showing the operation of the embodiment shown in FIG. 1 .

Fig. 3 are views for explaining the operation of the embodiment shown in Fig. 1,

Fig. 4 is a block diagram of a second embodiment of the present invention,

Fig. 5 is a flowchart showing the operation of the embodiment shown in Fig. 4, and

FIG. 6 is a flowchart showing the operation of the embodiment shown in FIG. 4.

It is now a first embodiment of the present Invention will be described with reference to the drawings. In this embodiment, a Time set at which a radio wave with the highest electric field strength received within 24 hours can be.

As shown in FIG. 1, this exemplary embodiment has a time output device 1 which outputs the time either visually, for example in the form of a digital display or an analog display with pointers, or acoustically. A receiving device 2 receives a radio wave which transmits time information which represents the day, the hour and the minute in the form of digital signals with a period of one second. The receiving device 2 has an antenna 2 a and a receiving circuit 2 b, which carries out the detection and other necessary operations. A counter 3 counts the frequency of reception of the radio wave by the receiving device 2 . A field strength detector device 4 determines the field strength of the radio wave received by the receiving device 2 and judges whether the detected field strength is below a predetermined value (50 dB in this embodiment). A buffer 5 temporarily stores field strength data and time information for each radio wave reception. A receiving condition storage device 6 selectively stores field strength data and time data. In this embodiment, the receiving condition storage means 6 is provided with storage areas so that it is possible to store up to five field strength data and also up to five time data as shown at (a) in FIG. 3. A time correction device 7 corrects the time output by the time output device 1 on the basis of the time information transmitted by the radio wave received by the reception device 2 . A control circuit 8 controls the processes for receiving time adjustment and time correction. The field strength detector device 4 , the buffer 5 , the reception condition storage device 6 and the control circuit 8 together form a detector device 9 which determines a time at which the radio wave can best be received. The reference number 10 denotes an alarm device, for example a buzzer.

Next, the reception timing and time correction operations will be explained with reference to the flowchart of Fig. 2 (which is composed of parts (a) and (b)).

When the power supply is turned on, under the control of the control device 8 , the respective contents of the buffer 5 and the reception condition storage device 6 are first deleted and the value N of the counter 3 is reset to "0".

Thereafter, the power supply for the receiver circuit 2 is b turned on under the control of the Steuerein device 8 receiving a radio wave by the reception device to start 2, and in step A is determined by the field strength detecting means 4, whether not the field strength of the received radio wave is less than 50 dB.

It turns out that the field strength is not less than 50 dB, under the control of the control device 8, the field strength data and the time information contained in the received radio wave are recorded and stored in the buffer 5 (step B).

Thereafter, the control device 8 checks whether any field strength data and time data of a radio wave received at the same time have already been stored in the reception condition storage device 6 (step C).

Since now in the receiving condition memory means 6 no data is stored, the field strength data and the time data resulting from the time information stored in the buffer 5 are in step D in the Empfangsbe dingungsspeichereinrichtung 6 stored, as shown at (b) in Fig. 3, and the time output by the time output device 1 is corrected based on the time information stored in the buffer 5 (step E).

Then the value of counter 3 is increased by "1" in step F.

Since the value of the counter 3 is now less than "24", the power supply for the receiving circuit 2 b is switched off to interrupt the radio wave reception for one hour (step G).

After an hour, the power supply for the receiving circuit 2 b is switched on to receive the radio wave again. If the field strength of the received radio wave is not less than 50 dB, the field strength data and the time data are stored in the reception condition storage device 6, and the time correction is performed based on the time information stored in the buffer 5 in the same manner as above (steps A to E). In addition, the value of the counter 3 is increased to "2" (step F). It should be noted that in the reception condition storage means 6, the data are sequentially stored in the order of decreasing field strength, as shown at (c) in FIG. 3.

Incidentally, if it is determined in step A that the electric field strength of the received radio wave is below 50 dB, then it is checked whether any data about the radio wave received at the same time has already been stored in the reception condition storage device 6 (step H) . If this is not the case, ie if it has not been 24 hours since the power supply was switched on in the exemplary case that the radio wave is received every hour, then the process proceeds to step F, where the value of the counter is " 1 "is increased.

If a radio wave with a field strength of not less than 50 dB is received in a state where all the memory areas of the reception condition storage device 6 are occupied with data, as shown at (d) in Fig. 3, then a comparison is made between those minimal field strength representing data from the data stored in the reception condition storage device 6 and the field strength data obtained at the moment of reception and stored by buffer 5 instead (step I). It should be noted that the field strength data of the radio wave received by the current receiving operation is denoted by x, while among the data stored in the reception condition storage means 6, those presenting the minimum field strength re are denoted by y.

If it is determined in step I that the field strength data x stored in the buffer 5 is larger than y, the data y corresponding to the minimum field strength is deleted in the reception condition storage means 6 (step J) and the field strength data x in the memory area instead of the minimum field strength data y stored. In addition, the time correction is carried out on the basis of the time information stored in the buffer 5 (step E).

In this way, the radio wave is received every hour, and if its electric field strength is not less than 50 db, the data transmitted over the received radio wave is recorded. If the value of the counter 3 "24" it reaches, that is, if the receiving operation is ended for 24 hours, the power supply for the receiving circuit 2 b is switched off to suspend the radio wave reception (step K).

In this way, up to five field strength data and also up to five time data in the order of decreasing field strength are stored in the receiving condition storage device 6 sequentially at the times during 24 hours when a radio wave with a field strength of not less than 50 dB is received.

Thereafter, the control device 8 judges whether or not any data is stored in the reception condition storage device 6 (step L).

If it is determined in step L that no data has been stored in the reception condition storage device 6 , an alarm is output via the alarm device 10 (step M). That is, an alarm is given if after 24 hours no radio wave with a field strength of not less than 50 dB has been received and thus no data has been stored, informing the user that the time information is not being received satisfactorily throughout the day can be. For example, the user can respond by changing the location where the clock is installed.

After a time has been determined in the manner described above at which there are good reception conditions, the control device 8 checks whether the time corresponding to the maximum field strength under the data stored in the reception condition storage device 6 corresponds to the time output by the time output device 1 or not (step N).

If the two times match, the power supply for the receiving circuit 2 b is switched on so that the radio wave is received by means of the receiving device 2 .

If the field strength of the radio wave is not less than 50 dB, all data of the radio wave are recorded, and the control device 8 then checks in step C in the same way as above whether data about the radio wave that was received in the past at the same time, have been stored in the receiving condition storage device 6 or not. If data is stored in the reception condition storage device 6 , the stored field strength data are overwritten in step O with the field strength data obtained at the current reception. The time is then corrected and the value of the counter is increased by "1" (step F).

Since the value of the counter after the completion of the operation for determining a time when the reception conditions are good during the 24 hours is "24" or more, the flow advances to step K, where reception is suspended. Subsequently, the flow advances to step N, where the system is put into the ready-to-receive state up to the time under the times stored in the reception condition storage device 6 , which corresponds to the maximum field strength. When the field strength data newly written in step O is no longer the maximum of the field strength data stored in the reception storage device 6 , the time is determined as the reception time which corresponds to the field strength data which are currently the maximum.

If the field strength data of the radio wave received at the time corresponding to the maximum field strength data described above is less than 50 dB, the flow advances to step H, where the controller 8 judges whether ir in the reception condition storage device 6 whatever data is stored about the radio wave that was received at the same time in the past or not. If data is stored in the reception condition storage means 6 , it is decided that the reception of the radio wave is not good at this time, and the affected field strength data and time data are deleted (step P).

Next, the control device 8 checks whether or not any data is still stored in the reception condition storage device 6 (step Q). If there is still data stored, the flow advances to step N through steps F to L, and the system is placed in the ready-to-receive state until the time corresponding to the maximum field strength data among the stored times.

If, on the other hand, it is determined in step Q that no data is stored in the reception condition storage device 6 , then this means, for example, that the stored data parts have been deleted one after the other because, in succession, the condition occurred that the field strength at that point in time the times stored in the receiving condition storage device 6 corresponds to the maximum field strength data, received radio wave is below 50 dB, which led to the deletion of all data. In such a case, the value of counter 3 is reset to "0" in step R. Then, the flow advances to step G, and reception of the radio wave is carried out an hour later. In this case, since the value of the counter 3 has been reset to "0", the radio wave reception is repeated every hour in the manner described above until 24 hours have elapsed. In other words, when all of the data in the reception condition storage device 6 has been deleted, the operation for determining a timing of good reception conditions is carried out again.

This way, a point in time within a day, too the reception conditions are good, automatically determined and the time correction automatically becomes the determined one Time executed.  

Next, a second embodiment of the present ing invention explained with reference to the drawings. In this embodiment, a Time at which an electric field strength of not less than 50 dB is available and at which the Error frequency in the time information recording minimal is.

It should be made in this regard to FIG. 4, are charged in the same reference as in Fig. 1 denote the same parts. In this embodiment, for each radio wave reception, a buffer 11 temporarily stores the time information transmitted with the received radio wave and error number data representing the number of times an error occurred when the time information was recorded. A reception condition storage device 12 selectively stores error number data and time data and is provided with storage areas so that it is possible to store up to five parts of error number data and also up to five parts of time data in the same manner as the reception condition storage device 6 in the above described first embodiment. A control device 13 controls the processes for setting the reception time and for time correction. A memory t stores the time information of three frames. The memory t is divided into three memory areas, ie t1 to t3, so that the time information of one frame is stored in each memory area. A counter c counts the number of times, that is, the number of times an error occurs when the received time information is received. The field strength detector device 4 , the buffer 11 , the reception condition storage device 12 , the control device 13 , the memory t and the counter c together form a detector device 9 .

Next, the reception time setting and time correction processes will be explained with reference to the flowchart of FIG. 5.

When the power supply is turned on, under the control of the control device 13 , the respective contents of the buffer 11 and the reception condition storage device 12 are first deleted and the value N of the counter 3 is reset to "0".

Then the reception of a radio wave begins by the receiving device 2 , and the field strength detector device 4 determines whether the electric field strength of the received radio wave is below 50 dB (step # 1).

If the determined field strength is not less than 50 dB, then the time information contained in the received radio wave is recorded under the control of the control device 13 , and an error number is determined. The error number data and the time information are then stored in step # 2 in the buffer 11 .

The error count determination, which is carried out in step # 2, is explained below with reference to the flow chart of FIG. 6. First, the counter c is reset to "0" and the content of the memory t is deleted. Then three frames of time information are received, that is, reception is carried out for three minutes. The received time information parts are stored one after the other for the individual frames in the memory areas t1 to t3 of the memory t. After completion of the reception of the time information of three frames, a comparison of the time information stored in the memory area t1, increased by one minute, and the time information stored in the memory area t2 is performed to determine whether these two time information match or not. If the two time information do not match, the value of the counter c is increased by "1". Then, a comparison is made between the time information stored in the storage area t1, increased by two minutes, and the time information stored in the storage area t3 to judge whether these two time information items are the same or not. If the two time information are not the same, the value of the counter c is increased by "1". Then, a comparison is made between the time information stored in the memory area t2, increased by one minute, and the time information stored in the memory area t3 to judge whether these two time information are the same. If the two time information are not the same, the value of the counter c is increased by "1". In the above-described manner, the frequency of occurrence of an error in recording the received time information is determined. More specifically, if neither the time interval between t1 and t2 nor the time interval between t2 and t3 is one minute, the value of the counter c becomes "3", which means that the reception conditions at that time are not good. If one of the following conditions is met, that is, the condition that the time interval between t1 and t2 is one minute, the condition that the time interval between t2 and t3 is one minute, and the condition that the time interval between t1 and t3 is two Minutes, the value of the counter c becomes "2", which means that the reception conditions are good at this time. If the time interval between t1 and t2 is one minute, the time interval between t2 and t3 is one minute and the time interval between t1 and t3 is two minutes, then the value of the counter c becomes "0", which means that the reception conditions become this Timing is best. In other words, whether or not the received time information is correct is judged on the basis of whether the individual time intervals between the time information in the memory areas t1 to t3 are correct or not.

After completion of the error number determination described above, the control device 13 judges whether or not data about the received radio wave has been stored in the reception condition storage device 12 at the same time in the past (step # 3).

In the receiving condition memory device 12, since no data are now stored, the error count data and based on the time information time data stored in the buffer 11, in the Empfangsbedingungsspei chereinrichtung stored 12 (step # 4). Is then outputted by the time output device 1 time tion on the basis of the data stored in the buffer 11 time Informa corrected (step # 5), and then the value of the Tough-converter 3 to "1" (Step # 6).

Since the value of the counter 3 is less than "24", it is then checked whether the reception condition storage means 12 has a free area with no stored data (step # 7).

Since there is a free memory area at the moment, the power supply for the receiving circuit 2 b is switched off in order to suspend the reception of the radio wave for one hour (step # 8).

After an hour, the power supply for the receiving circuit 2 b is turned on to receive the radio wave again. If the field strength of the received radio wave is not less than 50 dB, error number data and time data are stored in the reception condition storage device 12 in the same manner as above, and the time correction is carried out based on the time information stored in the buffer 11 (steps # 1 to # 5). Then the value of the counter 3 is increased to "2" (step # 6). It should be noted that the individual data parts in the receiving condition storage device 12 are stored one after the other in the order of increasing number of errors.

If it is determined in step # 1 that the field strength of the received radio wave is less than 50 dB, it is checked whether or not the reception condition storage means 12 stores data of the radio wave received at the same time in the past or not (step # 9). If this is not the case, that is, in the exemplary case in which the radio wave is received every hour, it has not been 24 hours since the power supply was turned on, the flow advances to step # 6 where the value of the counter 3 is increased by "1".

In this way, the radio wave is received every hour and data is recorded when the field strength of the received radio wave is not less than 50 dB. When the value of the counter 3 reaches "24", that is, when the reception operation is ended for 24 hours, or when there is no free area in the reception condition storage device 12 , the power supply for the reception circuit 2 b is switched off in order to receive the radio wave suspend (step # 10).

In this way, up to five times are stored in the receive condition storage device 12 at which a radio wave with a field strength of not less than 50 dB is received, together with the respective error frequency when recording the time information at the respective reception time of the radio wave.

Subsequently, the control device 13 judges whether or not data is stored in the reception condition storage device 12 (step # 11).

If it is determined in step # 11 that no data has been stored in the reception condition storage device 12 , an alarm is output by the alarm device 10 (step # 12). That is, an alarm is given if after 24 hours no radio wave with a field strength of not less than 50 dB has been received, and therefore no data has been stored, which informs the user that the time information is not satisfactory throughout the day can be received. For example, the user can respond by changing the location where the clock is installed.

After a time has been determined in the manner described above when the reception conditions are good, the control device 13 then checks whether the time corresponding to the minimum number of errors stored in the reception condition storage device 12 corresponds to the time output by the time output device 1 (Step # 13). If the two times match, the power supply for the receiving circuit 2 b is switched on in order to receive the radio wave with the receiving device 2 . If the field strength of the received radio wave is not less than 50 dB, the individual parts of the data transmitted by the radio wave are recorded and then judged by the control device 13 in the same manner as above whether in the reception condition storage device 12 all the data on the at the same time in the Radio wave received in the past is stored or not (step # 3).

When data is stored in the reception condition storage device 12 , the stored number of errors data is overwritten with the number of errors data received at the current reception (step # 14). The time is then corrected and the value of counter 3 is increased by "1" (step # 6).

Since after determining a time when there are good reception conditions, either the value of the counter 3 is "24" or more or the reception condition storage means 12 has no free space, the flow advances to step # 10 where reception is suspended. Subsequently, the flow advances to step # 13, where the system is set in the reception ready state until it reaches the time which, under the times stored in the reception condition storage device 12 , corresponds to that which corresponds to the minimum number of errors. When the error number data overwritten in step # 14 is no longer the minimum error number data among the error number data stored in the reception condition storage means 12 , the time at the reception time corresponding to the error number data which is currently the minimum is determined.

On the other hand, if the field strength of the radio wave received at the time corresponding to the minimum error number data described above is less than 50 dB, the flow advances to step # 9, where it is checked by the controller 13 whether the receiving condition storage means 12 any data about the radio wave received at the same time in the past is stored or not. If data is stored in the reception condition storage means 12 , it is decided that the reception of the radio wave is not good at this time, and the affected time and error number data are deleted (step # 15).

Then, the control device 13 checks whether or not any data is still stored in the reception condition storage device 12 (step # 16). If data is still stored, the flow advances to step # 13 through steps # 6 to # 11, and the system is put in the standby mode until the time corresponding to the minimum number of errors of the stored times is reached.

On the other hand, if it is determined in step # 16 that there is no data stored in the reception condition storage means 12 , it means, for example, that the stored data portions have been erased in succession because successively there was a case where the field strength of the radio wave received at one time which corresponded to the minimum number of errors under the times stored in the reception condition storage means 12 was less than 50 dB, so that all data was deleted. In such a case, the value of the counter 3 is reset to "0" (step # 17). The process then goes to step # 8, and reception of the radio wave is carried out an hour later. In this case, since the value of the counter 3 has been reset to "0", the radio wave is received repeatedly every hour until there is no free memory area in the reception condition storage device 12 or 24 hours have passed. This is done in the same way as above. In other words, when all of the data in the reception condition storage device 12 has been deleted, the operation of determining a time when the reception conditions are good is performed again.

In this way, a time when the reception condition are good, automatically determined, and at the determined time a time correction is carried out automatically.

Although in the previous embodiments, a time within 24 hours at which the reception conditions are good are determined, it should be noted that the time duration for the search can be specified as required.

Further, although in the foregoing embodiments, the reception condition storage devices 6 and 12 are designed to store up to five pieces of time data, it should be noted that the number of pieces of time data that can be stored is not necessarily limited to this, and that the reception condition storage devices 6 and 12 could also be designed to store data only at a time when the reception conditions are best. It is also possible to save the field strength data or the reception error data and the time data for all reception times during the 24 hours and to select the time when the reception conditions are best from this stored data.

Further, although in the second embodiment, the memory cher t is designed so that it the time information of can store three frames, the storage capacity is not necessarily limited to this, but can be used as needed be specified.

Although further out in the second embodiment error number determination led the individual time information compared by frame, they could also be in units a predetermined number of bits are compared. At for example, the arrangement could be such that a bit white water comparison between the time information generated by Addi tion of two minutes to the time information stored in t1 tion is obtained, the time information obtained by addition from one minute to the time information stored in t2 is obtained and the time information stored in t3 follows and if there is a match between the three times in formations is found, the time information for which a match was found as correct information determined while if if there is one bit where there are no two Time information match, it is decided that the Reception conditions are not good at this time.

According to the present invention, a time when the Condition for radio wave reception is good, automatically determined, and the time correction automatically becomes the determined time executed. As a result, it is possible that User time and work for setting the reception time to save. It is also possible to solve the problem eliminate that no time correction can be made and power is wasted because of the time information cannot be received satisfactorily.

Claims (6)

1. radio clock, comprising:
a time output device ( 1 ) for outputting the time,
a receiving device ( 2 ) for receiving a radio wave containing time information,
a detector device ( 9 ) for determining a time at which the radio wave can be received most effectively by the receiving device ( 2 ), and
time correction means ( 7 ) for correcting the time output by the time output means ( 1 ) based on the time information contained in the radio wave received at the time obtained by the detector means ( 9 ). 2. A method for setting the reception time for a radio clock, comprising the steps:
Activating a receiving device ( 2 ) for receiving a radio wave containing time information at any desired time period or at a desired time,
Determining the reception conditions at the point in time at which the reception device is activated, and
Determining the time at which the radio wave can be most effectively received within a whole day at the reception time. 3. Procedure for time correction in a radio clock, comprising the following steps:
Determining a time at which a radio wave containing time information can be most effectively received as the reception time,
Activate a receiving device ( 2 ) at the reception time, and
Correcting the time based on the time information contained in the radio wave received at the reception time. 4. Procedure for time correction in a radio clock, comprising the steps:
Activating a receiving device ( 2 ) for receiving a radio wave containing time information, at any desired time period or at the desired time,
Determining the time and the reception conditions at the time when the receiving device is activated,
Determining a time at which the radio wave can be received most effectively at the reception time,
Activate the receiving device ( 2 ) at the receiving time, and
Correcting the time based on the time information contained in the radio wave received at the reception time. 5. A method for setting the reception time for a radio clock, comprising the steps:
Activating a receiving device ( 2 ) for receiving a radio wave containing time information at any desired time period or at the desired time,
successively storing information about time and reception conditions at the time when the reception device is activated, in a storage device, in total or selectively, and
Determining a time that corresponds to the best reception conditions from those stored in the storage device ( 6 ), at the reception time. 6. Procedure for time correction in a radio clock, comprising the steps:
Activating a receiving device ( 2 ) for receiving a radio wave containing time information at any desired time period or at the desired time,
successive storage of information about time and reception conditions at the time when the reception device is activated in a storage device ( 6 ; 12 ), in total or selectively,
Determining a time that corresponds best to the reception conditions stored in the storage device at the reception time,
Correcting the time based on the time information contained in the radio wave received at the reception time
Determining the reception conditions at the time when the time correction is carried out, and
Refreshing the content of the storage device based on the determined reception conditions.