EP2129534A1 - Device and method for determining vehicle data, particularly tire pressure data - Google Patents

Abstract

The invention provides a device and to a method for determining vehicle data, particularly tire pressure data. The device has a transmitting unit, a receiver unit, and a measuring unit. The transmitting unit and/or the receiving unit are battery-operated. The receiving unit is a threshold receiver, or a carrier ID receiver.

Description

 description

title

Device and method for determining vehicle data, in particular tire pressure data

State of the art

The invention relates to a method for processing vehicle data, in particular tire pressure data according to the preamble of the main claim. German Patent Application DE 198 53 000 A1 discloses a method for supplying a motor vehicle with data. In this case, data is transmitted at fixed time intervals by means of a wireless communication device. For example, the data must have an end mark for this purpose in order to inform the receiving unit of the end of the data transfer. A disadvantage of the specified method, however, is that the system thus constructed can not be operated battery-powered, since the receiving unit must have a complex structure for data acquisition and thus has a high energy requirement. A system constructed in this way would no longer function quickly after the battery has been discharged.

Disclosure of the invention

In the device according to the invention according to the main claim or the independent claims, a power-saving threshold receiver or carrier ID receiver is used as the receiving unit. In an advantageous manner, the energy requirement of the receiving unit according to the invention is thus reduced compared to receivers of complex design. An energy supply of the invention

Device by means of a battery is therefore possible without the life of the device is significantly reduced by a depleted battery and without having to take costly measures to generate energy. A receiving unit is to be understood as a component for receiving signals and for sending signals. Depending on the operating mode set, the receiving unit therefore receives or transmits signals. However, it will be discussed below only by the receiving unit, as in the method according to the invention, the reception of signals from this component is important. The transmission unit according to the invention is likewise a component which receives and transmits signals as well. Since the transmission of the signals from this component is of particular importance in the method according to the invention, the component is referred to as a transmitting unit.

If the device is provided for processing or measuring tire pressure data, the wheel electronics preferably have the receiving unit. Advantageously, the receiving unit is spatially close to the point at which the tire pressure data are measured.

Preferably, the device has a trigger transmitter in the transmitting unit. By using a trigger transmitter, the energy requirement of the device is also preferably reduced because the receiving unit is not constantly addressed by the transmitting unit.

Preferably, the transmitting unit transmits at a frequency of about 80 to 250 kHz, more preferably at a frequency of about 110 to 150 kHz, most preferably at a frequency of about 120 to 130 kHz. Advantageously, this can improve the electromagnetic compatibility of the device.

Another object of the invention is a receiving unit for use in the device according to the invention. The receiving unit, but also the transmitting unit or the measuring unit, can preferably also be used with other components that do not belong to the device.

Another object of the present invention is a method for controlling the device. In this case, the communication of a transmitting unit with a receiving unit in a tire pressure monitoring system is preferred. System (TPMS) controlled. The transmitting unit transmits a signal to the receiving unit during a radio transmission. The receiving unit and / or the transmitting unit are battery-operated, wherein a threshold value receiver or a carrier ID receiver is used as the receiving unit. By using a simple threshold receiver or carrier ID receiver, it is advantageously possible to keep the energy consumption of the receiving unit low. In addition, advantageously the signal is very straightforward. The construction of the signal with an initial mark and / or an end mark is thus not necessary. As a result of the simple signal structure, it is also possible to use a transmission unit which has a simple design, and this also advantageously requires less energy than a complex transmission unit.

In the radio transmission of the signal, a first signal component with at least one radio signal and a second signal component with at least one radio signal are preferably transmitted. Preferably, the first signal component is transmitted in a first time interval and the second signal component in a second time interval from the transmitting unit to the receiving unit, wherein both the first time interval and the second time interval are greater than is necessary for the transmission of the radio signals in the respective time interval. This means that, for example, there may be a gap between two radio signals that are sent in a time interval. In this gap, preferably no radio signals are transmitted from the transmitting unit to the receiving unit or the transmitting unit does not transmit any signals in this gap or the transmitting unit radiates no energy in this gap. The time interval is thus larger by the gap, as for the actual

Transmission of the radio signals without gap is necessary. Of course, more than two or only one radio signal can be sent in one of the time intervals, wherein in a plurality of radio signals gaps between the radio signals may occur. The gaps and the radio signals are arbitrarily distributed in the first and / or in the second time interval, wherein the gaps preferably have a minimum length. In the following, a plurality of radio signals that are transmitted are assumed. Preferably, the radio signals received by the receiving unit are processed or not in response to the radio signal from the receiving unit. If, for example, a threshold receiver is used as the receiving unit, then, for example, the radio signals which exceed the threshold value are counted. The receiving unit thus processes these radio signals by counting these radio signals. If the radio signals do not exceed the threshold value, the radio signals are not counted, for example, and thus are not processed by the receiving unit. If a carrier ID receiver is used as the receiving unit, only the radio signals which have a specific carrier frequency (as carrier ID) are preferably counted. Of course, the receiving unit, the radio signals only receive and forward. In this case, processing of the radio signals (for example as just described) is taken over by another device.

Preferably, the device changes its operating mode when in the first and in the second time interval, a predetermined number of radio signals is processed by the receiving unit. For example, the measuring unit can be activated if the receiving unit has counted the same number of radio signals in the second time interval as in the first time interval. In this case, for example, the measurement of the tire pressure can be carried out by the measuring unit. The measured data can then be sent, for example, by the receiving unit, when it has switched to a transmission operating mode.

The device preferably does not change its operating mode if, during the first time interval and in the second time interval, a number of radio signals deviating from the predetermined number is processed by the receiving device. If the number of radio signals counted, for example in the second time interval, is not equal to the number of radio signals counted in the first time interval, preferably no measurement of the tire pressure is carried out by the measuring unit. The receiving unit remains in this case preferably in the receive mode.

Particularly preferred are the number of processed radio signals in the first and in the second time interval different operating modes of the device selectable. However, a change of the Bethebsmodus the device is particularly preferred only if the number of counted radio signals in the second time interval is equal to the counted radio signals in the first time interval. Particularly preferably, each possible operating mode of the device is assigned a predetermined number of radio signals in the first and / or in the second time interval. Depending on the number of processed radio signals while another operating mode of the device is called or started. For example, the device may transition from a sleep mode to a measurement mode if the number of counted radio signals has been three in each of the first and second time intervals. In the case of a number of, for example, two counted radio signals in the first and in the second time interval, the device can, for example, evaluate and send measured data, for example of the tire pressure. For example, in the case of a counted radio signal in the first and in the second time interval, the device changes to the idle mode. Of course you can only

Components of the device change their operating mode. For example, only the receiving unit in a counted radio signal in the first and in the second time interval in a sleep mode.

Preferably, the length of the first and / or the second time interval is defined. This advantageously prevents radio signals that are transmitted in the first time interval from being inadvertently counted to the second time interval or vice versa. However, it is also conceivable that the length of the first and / or the second time interval are determined by radio signals. For example, an initial radio signal and / or an end radio signal can be transmitted by the transmitting unit, whereby the length of the time intervals for the receiving unit are clearly limited. Such an initial and / or final radio signal may, for example, have a specific frequency or a specific transmission duration.

Short description of the drawing

Embodiments of the invention are illustrated in the following drawings and are explained in more detail in the following description. FIG. 1 schematically illustrates a receiving unit and a transmitting unit.

FIG. 2 schematically illustrates a method for controlling a device.

Embodiment (s) of the invention

FIG. 1 schematically shows a transmitting unit 12 and a receiving unit 13. In the method according to the invention, the transmitting unit 12 transmits radio signals to the receiving unit 13. However, the transmitting unit 12 can also receive data from the receiving unit 13 and the receiving unit 13 can send data to the transmitting unit 12 accordingly. The arrow 14 illustrates this bidirectional data exchange between the receiving unit 13 and the transmitting unit 12 schematically. However, the receiving unit 13 can also from other devices (not shown) receive data, as the arrow 15 represents. Furthermore, the receiving unit 13 can also send data to other devices, as the arrow 16 represents. The data transmission between the receiving unit 13 and the other devices can be wired and / or carried out by a radio transmission. Another device may, for example, be a storage device which counts and / or stores the radio signals of the transmitting unit 12.

FIG. 2 schematically shows a flow diagram of a method for controlling a device. The method starts, for example, in step 1, in which the receiving unit 13 waits for the radio transmission of a signal from the transmitting unit 12. In step 2, the receiving unit 13 receives a first signal component, wherein the first signal component is transmitted in a first time interval. The transmission of the first signal component in the first time interval represents step 3. In the first time interval, radio signals are preferably transmitted as the first signal component, wherein the radio signals can be processed by the receiver unit 13 or not. The processing of the radio signals is preferably carried out in such a way that the number of radio signals which, for example, exceed a threshold value or have a specific carrier frequency as a carrier ID, is counted. In step 4, the count of these radio signals. The number of counted radio signals in the first time interval is for example as Value N stored. Until the end of the first time interval, the receiving unit 13 waits for the transmission of further radio signals, as represented by step 5. At step 6, the second time interval begins. In step 7, radio signals are received in the second time interval. These radio signals are preferably counted if they have the same carrier frequency or exceed the same threshold value as the radio signals in the first time interval. The number of counted radio signals is stored as value M, for example. In step 8, until the end of the second time interval, all received radio signals are counted accordingly or not. After the second time interval, the values N and M are compared. In point 9, for example, the number of counted radio signals in the first and in the second time interval is the same. This is followed by step 10, in which, for example, different operating modes of the device are started. Depending on the values N, M, different operating modes of the device can be selected in step 10. For example, if N and M stand for three counted radio signals, for example, a measurement of a tire pressure of a vehicle is made. If the number of counted radio signals is unequal in the first and second time intervals, as represented by point 11, there is no change in the operating mode of the device. Instead, the receiving unit 13 again waits for the radio transmission of the transmitting unit 12, as in the step 1. Preferably, there are so many different variations of the values N, M as there are operating modes of the device. For example, in three modes of operation of the device, three different numbers of radio signals may be stored as N, M values. The device according to the invention can have a cost-effective transmitting unit 12 and a cost-effective receiving unit 13 due to the uncomplicated method. Advantageously, the energy consumption of the receiving unit 13 and the transmitting unit 12 used is very low, so that the device can be operated with a battery for power supply or for energy supply. Since a change in the operating mode of the device takes place only when there are a predetermined number of counted radio signals in the first and in the second time interval, the device only changes to a different operating mode in the case of such a double polling. As a result, the device becomes more reliable, since the probability of a change to a wrong operating mode due to a false signal transmission between Transmitting unit 12 and receiving unit 13 is reduced. In addition, this also saves energy at the same time, since, for example, other components of the device are not started erroneously when the device is changed to a wrong operating mode. Such components may be microcontrollers, for example.

Claims

claims

1. A device for processing and measuring vehicle data, in particular tire pressure data, the device having a receiving unit (13), a transmitting unit (12) and a measuring unit, wherein at least one of the units (13, 12) is battery-operated, characterized in that the receiving unit (13) is a threshold receiver or a carrier-ID receiver.

2. Apparatus according to claim 1, characterized in that the

Wheel electronics of a vehicle, the receiving unit (13).

3. Device according to one of the preceding claims, characterized in that the device comprises a trigger transmitter in the transmitting unit (12).

4. Device according to one of the preceding claims, characterized in that the transmitting unit (12) transmits at a frequency of about 80 to 250 kHz, preferably from about 110 to 150 kHz, most preferably from about 120 to 130 kHz.

5. Receiving unit (13) for use in a device according to one of the preceding claims, wherein the receiving unit (13) has both a reception mode and a transmission mode.

6. A method for controlling a device according to one of the preceding claims, wherein the transmitting unit (12) by radio transmission sends a signal to the receiving unit (13), characterized in that the receiving unit (13) and / or the transmitting unit (12) are battery powered , wherein as a receiving unit (13) a

Threshold receiver or a carrier ID receiver is used.

7. The method according to claim 6, characterized in that in the radio transmission, a first signal component with at least one radio signal and transmitting a second signal component with at least one radio signal, the first signal component being transmitted in a first time interval and the second signal component being transmitted by the transmitting unit (12) to the receiving unit (13) in a second time interval, wherein both the first time interval and the second signal component second time interval are significantly larger than is necessary for the transmission of the radio signals in the respective time interval.

8. The method according to any one of the preceding claims, characterized in that the receiving unit (13) processes the received radio signals in response to the radio signals or not.

9. The method according to any one of the preceding claims, characterized in that the device changes its operating mode when in the first and in the second time interval, a predetermined number of radio signals from the receiving unit (13) is processed.

10.Verfahren according to any one of the preceding claims, characterized in that the device remains in its operating mode, if in the second time interval and in the first time interval deviating from the predetermined number of radio signals from the

Receiving unit (13) is processed.

11.Verfahren according to any one of the preceding claims, characterized in that the length of the first time interval and / or the second time interval is defined.

12. The method according to any one of the preceding claims, characterized in that different operating modes of the device are set in dependence on the number of processed radio signals in the first and in the second time interval.