EP1077438A1 - A method for central gathering of a data - Google Patents

Abstract

The method involves matching the switch-on times and durations of the receiver to the transmission times of the transmitters, which transmit at different times. Each transmission of data takes place periodically within a period up to the next planned data transmission of new data with an integral number of repetitions, the different data transmissions of the individual transmitters take place in total in a periodically repeating time interval and the individual data transmissions of the different transmitters have fixed associated transmission times within the time interval.

Description

The invention relates to a method for central detection of data sent from different senders to one Receivers are transmitted wirelessly, with the switch-on times and the respective duty cycle of the receiver matched to the transmission times of the corresponding transmitters and the transmissions of the respective stations take place at a distance from each other.

Such methods are known from practice, in which the respective transmission times of the individual stations more or less complex algorithms both in the transmitter as well as in the receiver for the following transmission first be determined after the previous transfer. The for determining the future transmission times in the receiver required computing power causes energy consumption, of either the operating time of the receiver with given or restricted size limits sets or when using a larger energy storage has a negative impact on the size. Also affects the required computing power on the complexity of the usable computer, which is also not insignificant Costs are incurred.

The object of the invention is to overcome the aforementioned disadvantages to avoid and a procedure of the type mentioned specify the cost and energy consumption of the Receiver are reduced and reception on the transmitter side Transfers is ensured.

This task is solved by a centralized procedure Capture data from different senders a receiver can be transmitted wirelessly, the switch-on times and the respective duty cycle of the receiver on the transmission times of the corresponding stations be matched and the transmissions of each Transmitters are spaced apart from each other and wherein any data transmission within the period up to next scheduled transfer of new data with a integer repetitions are repeated periodically, the different data transmissions of the individual transmitters in its entirety in a periodically repeating Time interval take place and the individual data transfers of the various transmitters within this time interval have permanently assigned transmission times. Hereby above all, the energy consumption of the receiver reduced, since a complex calculation of the next broadcast date due to the permanently assigned transmission times. Those already programmed into the transmitters during production respective broadcast times can either when installed in the receiver as time value or Channel number can be entered or through a test run until the next scheduled transfer, that is "Play through" an entire cycle, read in and to be "learned".

The data transmissions of the various Transmitter within a section of the repetitive Time interval take place so that all transmissions take place within a limited period of time and there are also transmission-free time periods. This can be particularly advantageous if several independent systems with a process of this kind at the same time operated in close spatial proximity; then each system can have a certain portion of the time are assigned and overlaps or mismatches can be avoided.

According to the invention, the transmitters can be at least approximately continuous Have serial numbers and the individual transmission times of the various transmitters depending on the serial number be so that a systematic connection between serial number and time of transmission exists. This will help usual use cases where during installation the transmitters roughly in order from a larger one Packing unit for assembly in the object, one Overlap or the simultaneous transmission of several stations, what would hinder transmission. Be too through this connection when exchanging transmitters, e.g. B. in the case of defects, conclusions on the time of transmission based on the serial number and a replacement transmitter can be programmed accordingly.

The serial numbers can be strictly continuous run away, but they can only be roughly continuous be, e.g. B. by failure or lack of some transmitters assembly or by exchanging transmitters during operation. In this respect, both gaps in the operation consecutive order may arise, however also some serial numbers outside the other range lie. This will take advantage of this method partially weakened, but this has an effect only from a certain percentage of gaps or "Outliers" noticeably.

In a preferred embodiment of the invention the time of transmission of the individual transmitter within of the time interval or of the partial area of the time interval by being determined from an even distributed and starting from zero continuously numbered number of possible transmission times within of the time interval or of the partial area of the time interval the corresponding time to be broadcast by reversing the numerical order of a number of the last Digits of the serial numbers is determined, the Minimum number of possible transmission times through the base of the number system used exponentiates with the number the location to be reversed. Hereby becomes an even distribution due to the reversal of the Digit order is achieved and it's not a small one Partial area crowded with transmissions and another Part of the time interval remains unused. there can the serial numbers or their final digits in one any number system can be reversed, e.g. B. hexadecimal, Octal or binary system, the distribution uniformity roughly inversely proportional to the base of the number system rises or falls. So that's it Binary number system works best because it matches the smallest possible basis enables the most even distribution. The number of possible transmission times is included on the one hand by the transmission length of the respective Transfers and the minimum distance between two transfers from each other to avoid overlap upwards limited, on the other hand, it must be with the usual number of channels and transmission frequencies above a minimum value be arranged.

Advantageously, at least the serial numbers can each in a number system that differs from the decimal system, in particular as binary numbers, so that an even distribution of the transmission times as possible within a given time interval regardless of the number of transmissions or transmitters done automatically. Depending on the number system the numbering of the possible transmission times and / or the serial numbers are given, can meanwhile Conversions are made from one number system to another.

According to the invention, if a data transmission is not received with the next retransmission in the following The time interval for switching on the receiver is brought forward and the duty cycle can be extended so that even if there is a time difference between the transmitter clock and the receiver clock a reception on the next retransmission probably done.

The recipient can continue to receive a data transfer for transmissions from this transmitter to the next Scheduled transmission of new data switched on again so that additional energy is saved. With increasing number of transmissions already received can thus greatly reduce energy consumption become.

The time of transmission can preferably be within the time interval or part of the time interval at least once within retransmissions, in particular varies on the last retransmission so that in any case, if necessary by addition the transmission time variation and the receiver side Advancement of the switch-on time and extension of the Duty cycle a match of transmission time and receiver activation is achieved and transmission reception is ensured. This variation can for example, in that - different from the previous retransmissions - on the last one Retransmission is currently no reversal in order to assign the time of transmission takes place or only a small part the sequence of digits is reversed. Thus all transmitters get once within the repetition period either one completely different broadcast date or a little unscheduled deviation within the duty cycle, making the transmission probability clear is increased. In the case of non-reversal, the other can Sending time either by programming or "Learn" can be entered into the recipient, with partial reversal this is not necessary since the transfer because of the small deviation within the duty cycle lies. It can also cause such a small deviation achieved that z. B. the front part of the to be reversed Sequence of digits by swapping from the original rear digits is replaced, but also partially remain in their rear position.

A time correction can advantageously be carried out on the receiver side to compensate for deviations between transmitter time determination and receiver time determination take place, with time correction the deviation of the corresponding last reception can be extrapolated from its target time.

This can result in a deviation of the respective internal Time determinations of sender (s) and receiver compensated be, so that the corresponding transmission at an earlier (retransmission) transmission is received and the recipient does not repeat for this transmission and also does not have to be activated for a longer period (s), whereby again energy is saved.

The following is an example explained. In the described case, each day transmit a data record from each transmitter to the receiver become. Here, the data transfers within the period until the next scheduled transfer, d. H. repeated five times within one day. In doing so the transmissions of the individual stations in one repeating periodic interval of four Hours and are within a portion of this time interval, namely the first hour summarized. In this respect, the respective data transfers take place in the times from zero to one, four to five , Eight to nine, twelve to one, four to five and 8 p.m. to 9 p.m. daily.

It is still assumed that simplicity only 16 transmitters are provided, their serial numbers run from zero to 15. The partial area of the time interval (1 hour) also only shows for this reason 16 evenly distributed transmission times on the spaced three minutes and 45 seconds apart are.

The data transfers each take only a few tenths Seconds. According to the invention described here The procedure is the serial numbers given in decimal numbers the transmitter (column 1 of the table) for distribution of the transmission times in accordance with column 2 of the table as Binary numbers are given, these are then reversed (column 3) and these inverted binary numbers are in turn indicated as decimal numbers according to column 4 of the table. These then designate the corresponding time of transmission.

This results in a distribution of the transmission times (Column 4) on the respective transmitter (Column 1) accordingly the table.

When installing such a method, the transmission times can either be programmed into the receiver or "learned" through a test run. In later operation, the receiver can refrain from switching on the retransmission corresponding to this transmitter when a transmission is received; if a transmission has not been received, he can successively increase the time window for switching on the receiver during the following repetitions. It is also possible to provide a more or less strong variation of the transmission time in the transmitter during the last repetition of a day, e.g. B. by the fact that the transmission times are distributed without reversal or, in the reversal, some digits retain their old value despite the reversal, as a result of which a slight variation is achieved. In such a case, overlaps of different transmissions can be compensated for by the changed transmission times. Channel Time of transmission Serial number normal (decimal number) Serial number normal (binary number) Reverse serial number (binary number) Reverse serial number (decimal number) 0000 0000 0000 0000 0001 0001 1000 0008 0002 0010 0100 0012 0003 0011 1100 0004 0004 0100 0010 0014 0005 0101 1010 0006 0006 0110 0110 0010 0007 0111 1110 0002 0008 1000 0001 0015 0009 1001 1001 0007 0010 1010 0101 0011 0011 1011 1101 0003 0012 1100 0011 0013 0013 1101 1011 0005 0014 1110 0111 0009 0015 1111 1111 0001

Claims (10)

Process for the central collection of data by different transmitters wirelessly to a receiver be, the switch-on times and the respective Duty cycle of the receiver on the transmission times of the corresponding broadcaster and the Broadcasts of the respective stations to each other in time spaced apart, characterized in that each Data transmission within the period up to the next Scheduled transmission of new data using an integer Repetitions are repeated periodically, the different Data transmission of the individual transmitters in their Whole in a periodically repeating Time interval take place and the individual data transfers of the various transmitters within this time interval have permanently assigned transmission times. A method according to claim 1, characterized in that the data transmissions of the various transmitters within a portion of the repeating time interval respectively. A method according to claim 1 or 2, characterized in that that the broadcaster is at least approximately continuous Have serial numbers and the individual transmission times the different transmitters are dependent on the serial number. A method according to claim 3, characterized in that the broadcast time of the individual broadcaster within of the time interval or of the partial area of the time interval it is determined that from an even distributed and consecutively numbered starting from zero Number of possible broadcast times within the Time interval or the partial area of the time interval the corresponding time of transmission to be perceived by reversing the numerical order of a number of the last digits the serial number is determined, the minimum number of the possible broadcast times through the base of the Number system used exponentiates with the number of reversing point is determined. A method according to claim 4, characterized in that at least the serial numbers are each in one of the decimal system deviating number system, especially as Binary numbers are given. Method according to one of claims 1 to 5, characterized characterized that if a data transmission is not received with the next retransmission in the following The time interval for switching on the receiver is brought forward and the duty cycle is extended. Method according to one of claims 1 to 6, characterized characterized in that upon receipt of a data transmission the Receiver for transmissions from this transmitter to the next Scheduled transmission of new data switched on again becomes. Method according to one of claims 1 to 7, characterized characterized that the time of transmission within the Time interval or partial area of the time interval at least once within retransmissions, varies especially in the last retransmission becomes. Method according to one of claims 1 to 8, characterized characterized that a time correction on the receiver side to compensate for deviations between transmitter time determination and recipient time determination takes place. A method according to claim 9, characterized in that to correct the time the deviation of the corresponding last reception extrapolated from its target time becomes.