EP1936449A1 - Method for wireless programming of a time signal receiver, wireless programmable time signal receiver and programming device for the wireless programming of a time signal receiver - Google Patents

Abstract

The method involves transmitting a programming instruction, which is coded in an adapted data format on a time signal receiver (210), of a transmitting device. A complete time signal according to the time signal protocol is assigned for programming of the time signal receiver, which has a programming instruction. Independent claims are also included for the following: (1) a programmable time signal receiver, which has a receiving unit for the wireless receiving of an electromagnetic time signal (2) a programming device for a wireless programming of a time signal receiver, which has a storing unit for the storage of instructions for the time signal receiver.

Description

The invention relates to a method for wireless programming of a time signal receiver, a wireless programmable time signal receiver and a programming device for wireless programming of a time signal receiver.

For a variety of daily life applications, providing accurate time is of paramount importance. In various nations, such as the USA, Japan, Russia, Germany, etc., the competent national institutions provide exact time signals, so-called time signals, which can be received with the aid of suitable receivers (time signal receivers). The time signals can be used for further processing, that is to say for the extraction of a precise time specification in suitably equipped terminals, in particular in radio-controlled clocks or time-based measuring devices.

For the transmission of time signals are radio waves, especially in the long-wave frequency range of about 30 kHz to about 300 kHz, a suitable medium. In long-wave signals, in particular by amplitude modulation, coded time signals have a very large range, they penetrate into buildings and they can still be received with very small ferrite antennas. Obstacles such as trees and buildings cause high signal attenuation in high-frequency satellite signals, but the reception of long-wave signals is only slightly affected by such obstacles.

The time signal is provided by a time signal transmitter which transmits a signal sequence according to a predetermined protocol. The national time signal transmitters differ both in the selected transmission frequency and in the structure of the protocol. A typical example is the long-wave transmitting station DCF-77 controlled by the Physikalisch Technische Bundesanstalt (PTB), which is controlled by several atomic clocks and emits a time signal with a power of 50 KW on the frequency 77.5 kHz in continuous operation.

A more detailed description of the protocol of the time signal transmitted by the DCF77 station is given below Figures 1 and 2 refer to. Examples of other time signal transmitters are WWVB (USA), MSF (Great Britain), JJY (Japan), BPC (China), which transmit time information on a longwave frequency in the range between 40 and 120 kHz using amplitude modulated signals.

In general, a time signal with a time frame of exactly one minute is transmitted to transmit the time information. This timeframe contains values for the minute, hour, day, day of the week, month, year, etc. in the form of BCD codes (binary coded decimal codes), which are transmitted with pulse duration modulation at 1 Hz per bit. Either the rising edge or the falling edge of the first pulse of a time frame is exactly synchronized with 0 seconds. A typical radio-controlled watch is designed such that the time adjustment takes place by recording the time information of one frame or a plurality of time frames from the time when the zero-second signal was first received.

Fig. 1 shows the coding scheme of the coded time information shown by reference A according to the protocol of the time signal transmitter DCF-77. The coding scheme here consists of 59 bits, with 1 bit corresponding to one second of the frame. In the course of a minute, a so-called time signal telegram can be transmitted, which contains information on time and date in binary coded form. The first 15 bits B contain general coding, for example operating information, and are currently not used. The next 5 bits C contain general information. Thus, R denotes the antenna bit, A1 denotes a Central European Time (CET) to Central European Summer Time (CEST) and backward announcement bit, Z1, Z2 denotes zone time bits, A2 denotes a leap second notification bit, and S denotes a start bit of the encoded time information. From the 21 bit to the 59th bit, the time and date information is transmitted in BCD code, with the data being valid for the following minute. The bits in area D contain information about the minute, area E information about the hour, area F information about the calendar day, area G information about the day of the week, area H information about the month and area I Information about the calendar year. This information is available bit by bit in coded form. At the end of areas D, E and I, so-called check bits P1, P2, P3 are provided. The sixtieth bit is unused and is for the purpose of indicating the beginning of the next frame. M denotes the minute mark and thus the beginning of the time signal.

The structure and bit assignment of the in Fig. 1 The timing signal transmission scheme illustrated is well known and is described, for example, in an article by Peter Hetzel, "Time Information and Normal Frequency", Telekom Praxis, Volume 1, 1993 described.

The transmission of the time signal information is amplitude modulated with the individual second marks. The modulation consists of a decrease X1, X2 or increase of the carrier signal X at the beginning of each second, at the beginning of each second - except the fifty-ninth second of each minute - in the case of a time signal emitted by the DCF-77 transmitter - the carrier amplitude for the duration of 0.1 seconds X1 or for the duration of 0.2 seconds X2 is lowered to about 25% of the amplitude. These reductions of different duration each define second marks or data bits. This different duration of the second marks is used for the binary coding of time and date, whereby second marks with a duration of 0.1 seconds correspond to X1 of the binary "0" and those with a duration of 0.2 seconds to X2 of the binary "1". Due to the absence of the sixtieth second mark, the next minute mark is announced. In combination with the respective second, an evaluation of the time information sent by the time signal transmitter is then possible. Fig. 2 shows an example of a section of such an amplitude-modulated time signal, in which the coding is carried out by lowering the RF signal with different pulse length.

Conventional time signal receiver, as described for example in the German patent DE 35 16 810 C2 are described, receive the radiated from the time signal transmitter amplitude modulated time signals and output it again demodulated as different lengths of pulses. This is done in real time, that is, per second, a pulse of different lengths at the output according to the idealized time sign according to Fig. 2 generated. The time information is encoded by the different length pulses of the carrier available. From the time signal receiver these pulses of different lengths are fed to a downstream microcontroller. The microcontroller evaluates these pulses and determines whether a bit value "1" or "0" is assigned to the respective pulse according to the length of this pulse. This is done by first determining the start of the second of a respective time frame of the time signal. If this start of the second is known, the bit value "1" or "0" can then be determined from the determined duration of the pulse. The microcontroller subsequently takes up every 59 bits of a minute and uses the bit codes of a respective second pulse to determine the exact time and exact date.

From the market, a time clock receiver designed as a radio clock with a radio movement is known, which is set up to receive a time signal. In order to make adjustments to the radio movement clock to different operating conditions and, where appropriate, to allow blocking or release of functions of the radio movement, the radio movement is programmable. That is, one or more programming instructions encoded according to a programming protocol stored in the radio-controlled clockwork may be fed into the radio to achieve the desired characteristics of the radio-controlled clockwork. For programming the radio clockwork a wired transmission of the programming instructions is provided. For the purpose of programming, the known radio clock has a plurality of contact surfaces in the area of a battery compartment, which can be acted upon by programming pins in a programming device of mechanical contact needles with programming signals. Thus, access to the pads must be left open to perform the programming operation, and each watch must be loaded into the associated programmer for programming. During the programming process, instructions for enabling or disabling functions of the watch or other parameters may be transmitted. Such functions are usually programmed permanently in the wristwatch and can be made available or locked depending on the scope of the wristwatch for the user, so that the same radio movement can be used for wristwatches with different functional scope.

Another programmable radio wristwatch is from the document DE 196 25 041 A1 known. The disclosed radio wristwatch can be subsequently programmed by means of a transponder device, among other things, the radio clock carrier frequency is used for the transmission of data. To do this, the watch is put into a programming state via an external, manually operated switch integrated in the watch.

The object underlying the invention is to provide a method for programming a time signal receiver, a time signal receiver and a programming device for programming a time signal receiver, which allow a simplified programming.

This object is achieved by a method having the features of claim 1, by a time signal receiver having the features of claim 10 and by a programming device having the features of claim 11. Advantageous developments of the invention are the subject of dependent claims.

The inventive method for wireless programming of a time signal receiver comprises the following steps: sending a programming instruction, which is encoded in a data format adapted to a time signal receiver, from a transmission device; receiving the programming instruction wirelessly by receiving means of a time signal receiver adapted to receive a time signal in accordance with a predeterminable time signal protocol; Decoding the programming instruction by the receiving means and / or by processing means of the time signal receiver, storing the programming instruction intended for execution in the receiving means and / or in the processing means in memory means of the time signal receiver. With the aid of the method according to the invention, parallel programming of a multiplicity of time signal receivers is possible since the programming instructions are transmitted without mechanical contact between a programming device and the time signal receiver. Thus, a programming of a time signal receiver can also be realized in mass production without the need for an uneconomically large number of programming devices. In addition, the provision of contact surfaces for wired coupling of the Programming instructions are omitted, whereby a simplification of the time signal receiver can be realized. It is also possible to program the time signal receiver even after installation in a more complex unit, for example in a measuring device or in a household appliance, without direct mechanical access. It is also conceivable to update programming instructions at a later time after completion of the time signal receiver. It is crucial that for the programming of the time signal receiver the access provided for the reception of the time signal is used to effect a wireless or contactless transmission of programming instructions. To carry out the method, a programming instruction is provided to the time signal receiver, which is written in a format decodable by the time signal receiver. Based on a first programming instruction, the time signal receiver can be made ready to receive further programming instructions. The receiving means of the time signal receiver is, in particular, an analogue receiver arrangement as described in US Pat German patent application DE 103 34 990 is described. The processing means may be embodied, for example, as a state machine or as a microcontroller. The processing means are assigned internally or separately executed storage means for storing at least one program instruction.

In an embodiment of the invention, it is provided that for programming the time signal receiver at least a complete time signal is transmitted in accordance with the time signal protocol, which additionally comprises a number of programming instructions. In such an approach, which can be used in particular for the time signal of the German DCF77 transmitter, a transmission of programming instructions is possible without the need to dispense with the transmission of the time signal. According to the protocol of the DCF-77 time sign, within the time frame which has a duration of 60 seconds in the DCF-77, the first 15 bits are freely available and can thus be used both for the transmission of a first programming instruction signal (first bit in FIG DCF-77 protocol) as well as for the transmission of further programming instructions (second to fifteenth bit in the DCF-77 protocol). Thus, a parallel programming of the time signal receiver and a synchronization of the time signal receiver to the for Programming emitted timing signals are made. After a programming phase, the full functionality of the time signal receiver including the ability to correctly synchronize to the time signal can thus be checked immediately. The disadvantage of a low data rate for the transmission of programming instructions within the time frame (usable bits per minute in the DCF 77 protocol), which can be several minutes, is readily absorbed by having a plurality of time-domain receivers in parallel from a single programming device can be programmed wirelessly.

In a further embodiment of the invention it is provided that for programming the time signal receiver in a first step, a time signal is transmitted, which includes at least one programming instruction for switching the time signal receiver to a programming protocol, and that in further steps programming instructions are transmitted according to a stored in the time signal receiver programming protocol. Such an approach comes into question when the time signal receiver is provided for a time-signing protocol in which only a few bits or even a single bit are available, as is the case with most time-sign protocols. For programming, the certificate receiver is first provided with a time signal according to the corresponding protocol, in which at least one free bit is set in accordance with a protocol stored in the time signal receiver so that it can be recognized during decoding in the time signal receiver that a programming operation is planned. The time signal receiver switches to a programming state upon arrival of the corresponding bit. In the programming state, a programming protocol deviating from the time signal protocol is used by the programming device, which is stored in the time signal receiver for decoding the programming instructions.

In a further embodiment of the invention, it is provided that programming instructions for programming the time signal receiver are transmitted in a programming protocol deviating from the time signal protocol, which is stored in the time signal receiver. The time signal receiver may be arranged to examine incoming signals for whether they are timing signals or programming instructions. The time signal receiver can also be set up such that it is switched to the programming state on the basis of a parameter associated with the time signal, for example based on the field strength of the time signal, or by a parameter independent of the time signal, for example by a programming status signal sent by the programming device. In a preferred embodiment of the invention, it is provided that the programming signal for switching to the programming state is derived from a field strength of the time signal. In this case, recourse can be made in particular to the variable amplification of the adjustable amplifier provided in the receiving means. A high field strength signal is detected by a minimum gain and indicates to the time signal receiver that programming is to be performed with a programmer,

In a further embodiment of the invention, it is provided that the time signal receiver is switched to the programming state upon receipt of the programming instruction for a predefinable period of time. This ensures that the time signal receiver always comes back to the receiving state for the time signal even without complete completion of the programming process.

In a further embodiment of the invention, it is provided that the time signal receiver is switched to the programming state upon receipt of the programming instructions until the arrival of a reset instruction. Thus, a variable number of programming instructions can be transmitted to the time signal receiver. Upon arrival of the reset instruction, the time signal receiver switches back to the reception state for the time signal and can be checked, for example, immediately after its programming operation for its reception properties for the time signal. This is advantageous when different production batches of time signal receivers are to be programmed with very different amounts of programming instructions. With a small number of programming instructions to be transmitted, the function test can be carried out with the time signal after a short time. In the case of a multiplicity of programming instructions, a return change to the receive state is made only after the entire transmission thereof.

In a further embodiment of the invention it is provided that in the programming state, a release or blocking of functions that are fixed in the time signal receiver, is made. The functions are provided in the layout, that is to say in the hardware of the time signal receiver, and can be blocked or released by means of internal pointers, that is to say by software. When performing the programming operation, the respective pointers are set according to the specification by the programmer and thereby determine the functionality of the time signal receiver. A typical application for such releasable and lockable functions is stopwatch or calendar functions on a wristwatch with radio movement. In the radio movement, these functions are all created on the hardware side and depending on the wristwatch model are enabled or blocked by software on the software side.

In a preferred embodiment of the invention, a final blocking of the programming state is provided after the programming has been carried out once. Such a blocking can be effected in particular by setting an internal pointer in the receiving means or in the processing means or by separating one or more electrical connections in the time signal receiver, for example by an externally irradiated signal with high field strength. This prevents a subsequent change of the program instructions transmitted in the programming process, which is of particular interest when determining different functional scopes for the time signal receiver.

In a further embodiment of the invention, it is provided that in the programming state, a freely programmable instruction sequence intended for execution by the receiving means and / or the processing means is stored in the memory means. With a freely programmable instruction sequence functions can be implemented in the time signal receiver, which are not already created in the layout of the time signal receiver. These may be, for example, country-specific parameters for decoding the time signal or additional software that is to run in the time signal receiver.

According to a further aspect of the invention, there is provided a programmable time signal receiver having receiving means for wirelessly receiving an electromagnetic time signal and / or a program instruction and processing means for processing the time signal and / or programming instructions, wherein the receiving means and / or the processing means are associated with memory means which are designed for temporary storage of programming instructions and for providing the instructions to the receiving means and / or to the processing means, the receiving means and / or the processing means being adapted to extract programming instructions from the time signal and / or from a programming signal and store the programming instructions in the memory means. The programming signal is a programmer coded with a plurality of programming instructions based on a programming protocol other than the timing log

According to a further aspect of the invention, a programming device for wireless programming of a time signal receiver is provided with memory means for storing instructions for the time signal receiver and with a transmission device, in particular a long wave transmission device, for providing an electromagnetic signal, and with a control device which is used to encode the instructions in FIG the electromagnetic signal is set up, proposed. With such a programmer, a plurality of time signal receivers can be programmed in parallel since no mechanical contact between the time signal receiver and the programmer is required. The programming device is preferably installed in an electromagnetically shielded room and the time signal receivers to be programmed are, if appropriate in large numbers, brought into the electromagnetic field emitted by the programming device. Depending on the design of the time signal receiver and the programming device, a parallel or a sequential execution of a programming and a function test directed to the time signal reception can be carried out, in particular for time signal receivers which are set up to receive and evaluate time signals according to the DCF-77 protocol ,

In a further embodiment of the invention, it is provided that the control device for coding a time signal with programming instructions in accordance with a predeterminable time signal protocol and for coding a programming instruction according to a predetermined programming protocol for time signal receiver is switchable. Thus, the programmer can be used in addition to the programming function for those time signal receivers that are not intended for a parallel implementation of programming and time signal reception, in a simple and cost-effective manner as a test device for the time signal reception.

Fig. 1

ein schematische graphische Darstellung eines Zeitzeichens, das gemäß dem Protokoll des Zeitzeichensenders DCF-77 codiert ist;

Fig. 2

einen Ausschnitt eines idealisierten Zeitzeichens mit 5 Sekundenimpulsen;

Fig. 3

ein Blockschaltbild eines stark vereinfacht dargestellten Zeitzeichenempfängers,

Fig. 4

ein detailliertes Blockschaltbild eines Teils des Zeitzeichenempfängers gemäß der Fig. 3.

Fig. 5.

eine schematische Darstellung eines Programmiergeräts für eine Vielzahl von Zeitzeichenempfängern gemäß einer Ausführungsform der Erfindung.

Further advantages and features of the invention will become apparent from the claims and from the following description of preferred embodiments, which are explained with reference to FIGS. Showing:

Fig. 1

a schematic diagram of a time signal, which is coded according to the protocol of the time signal transmitter DCF-77;

Fig. 2

a section of an idealized time sign with 5 second pulses;

Fig. 3

a block diagram of a highly simplified illustrated time signal receiver,

Fig. 4

a detailed block diagram of a portion of the time signal receiver according to the Fig. 3 ,

Fig. 5.

a schematic representation of a programmer for a plurality of time signal receivers according to an embodiment of the invention.

In all figures of the drawing, the same or functionally identical elements, signals and functions - unless otherwise stated - the same.

The basic structure and operation of a time signal receiver is from the German patent DE 35 16 810 known. Fig. 3 shows a block diagram of a highly simplified illustrated time signal receiver, present as Radio clock 100 is formed. The radio clock 100 has an antenna 2 for receiving the time signal 3 transmitted by a time signal transmitter 101. An integrated circuit 20 with a logic and control unit 30 is connected to the antenna 2. Antenna 2 and integrated circuit 20 together form the receiver 1. The outputs of the receiver 1 are followed by a program-controlled unit designed as a microcontroller 102 in the manner of processing means. The microcontroller 102 receives the data bits generated by the receiver, calculates therefrom an exact time and an exact date and generates therefrom a signal 105 for time and date. The radio-controlled clock 100 also has an electronic clock 103 whose time is controlled by means of a clock quartz 104. The electronic clock 103 is connected to a display 106, for example a display, via which the time is displayed.

Fig. 4 shows on the basis of a detailed block diagram the executed as an integrated circuit 20 part of the time signal receiver. The integrated circuit 20 has two inputs 21, 22 for connection to one or two antennas, not shown. By providing two or even more antennas, it is possible to tune the receiver 1 by switching between the antennas to different time signal transmitters operating in different wavelength ranges. With the switching, a frequency or antenna switching can be made. A variable gain amplifier 4 can be connected to one of the antenna inputs 21, 22 by means of controllable switches 23, 24. The other input of the control amplifier 4 is connected to inputs 21 22 '. In these inputs, for example, a reference signal IN1, IN2 can be coupled. The control amplifier 4 is connected on the output side to an input of a post-amplifier 7. In between, a designed as a capacitor designed filter 6 is arranged, can be compensated with the parasitic capacitances between the inputs QL - QH.

The integrated circuit 20 also has a switch unit 25. The switch unit 25 has, for example, a plurality of switchable filters at the inputs QL-QH, by means of which the switch unit 25 is designed to provide several frequencies on the output side. These frequencies can be adjusted via control inputs 26, 36, 37 of the switch unit 25. About one of the switch unit 25 provided Control signal 27, the control amplifier 4 can be influenced, in particular controllable. The switch unit 25 further generates an output signal 28, which is coupled into a second input of the post-amplifier 7. The post-amplifier 7 controls the downstream rectifier 8. The rectifier 8 generates a control signal 31 (AGC signal = automatic gain control), which drives the variable gain amplifier 4. The rectifier 8 also generates on the output side an output signal 29, for example a rectangular output signal 29 (TCO signal), which is fed to a downstream logic and control unit 30.

The logic and control unit 30 is connected to an input / output device 32 (I / O unit) which is connected to input / output terminals 33 of the integrated circuit 20. At these outputs 33, inter alia, the processed in the logic and control unit 30, decoded and stored time signals can be tapped. One of the integrated circuit 20 downstream - in Fig. 4 not shown - microcontroller or a state machine built simply state (state machine) can read just these stored in the logic and control unit 30 and decoded time signals as needed. Furthermore, a clock signal can be fed to the integrated circuit 20 or the logic and control unit 30 via the connections 33.

For further control of the switch unit 25, this is connected to the logic and control unit 30, which controls the logic and control unit 30 with a control signal 38. The integrated circuit further comprises terminals 36, 37, via which the logic and control unit 30 with control signals SS1, SS2 can be acted upon.

In the Fig. 5 a programming device 200 is shown which is provided for a simultaneous programming of a plurality of time signal receivers 210 designed as radio-controlled wristwatches. The programmer 200 has a plurality of adjusting knobs 220, 230, which are provided for setting the programming method or for setting the functions to be enabled in the time signal receivers. The programming device 200 has an antenna 240 for the transmission of a long-wave time signal or programming signal, so that a wireless programming or a transmission of a time signal to the time signal receiver 210 can be made.

Claims (11)

Method for wireless programming of a time signal receiver (100, 210) with the steps: Sending a programming instruction coded in a data format adapted to a time signal receiver (100, 210) from a transmission device (200), receiving the programming instruction wirelessly by means of receiving means (1) of a time signal receiver (100, 210) which is set up to receive a time signal in accordance with a predeterminable time signal protocol, Decoding the programming instruction by the receiving means (1) and / or by processing means (102) of the time signal receiver (100, 210), Storing the programming instruction intended for execution in the receiving means (1) and / or in the processing means (102) in storage means of the time signal receiver (100, 210). characterized in that
for programming the time signal receiver (100, 210), at least one complete time signal is transmitted in accordance with the time signal protocol, which additionally comprises at least one programming instruction. A method according to claim 1, characterized in that for programming the time signal receiver (100, 210) in a first step, a time signal is transmitted, which comprises at least one programming instruction for switching the time signal receiver (100, 210) to a programming protocol, and that in further steps Programming instructions are transmitted according to a stored in the time signal receiver (100, 210) programming protocol. Method according to Claim 1 or Claim 2, characterized in that, for programming the time signal receiver (100, 210), programming instructions in a programming protocol deviating from the time signal protocol, which is stored in the time signal receiver (100, 210). A method according to claim 3, characterized in that the programming signal for switching to a programming state is derived from a field strength of the time signal. A method according to claim 4, characterized in that the time signal receiver (100, 210) is switched on receipt of the programming instruction for a predetermined time period in the programming state. Method according to Claim 4 or Claim 5, characterized in that the time signal receiver (100, 210) is switched to the programming state upon receipt of the programming instructions until the arrival of a reset instruction. Method according to one of, claims 4 to 6, characterized in that in the programming state, a release or blocking of functions that are fixed in the time signal receiver (100, 210) is made. Method according to one of claims 3 to 7, characterized in that in the programming state for execution by the receiving means (1) and / or the processing means (102) certain, freely programmable instruction sequence is stored in the memory means. Programmable time signal receiver (100, 210): - With receiving means (1), which are designed for wirelessly receiving an electromagnetic time signal and / or a programming instruction, and - With processing means (102), which are designed for processing the time signal and / or a programming signal, wherein the receiving means (1) and / or the processing means (102) are associated with memory means for temporary storage of instructions and for providing the instructions to the receiving means (1) and / or to the processing means (102), characterized in that the receiving means (1) and / or the processing means (102) are adapted according to a method according to claims 1 to 8, to remove programming instructions from the time signal and / or from a programming signal and to store the programming instructions in the storage means , Programming device (200) for wireless programming of a time signal receiver (100, 210): - with memory means for storing instructions for the time signal receiver (100, 210), - With a transmitting device (240), in particular a long-wave transmitting device, for providing an electromagnetic signal comprising at least a complete time signal according to a time signal protocol, and - With a control device, which is adapted to encode the instructions in the electromagnetic signal. Programming device according to claim 10, characterized in that the control device for coding a time signal with programming instructions in accordance with a predetermined time signal protocol and for coding a programming signal according to a predetermined programming protocol for time signal receiver (100, 210) is switchable.

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