EP2953820A1 - Method and device for detecting the presence of objects in a passenger compartment of a vehicle - Google Patents

Abstract

The invention relates to a method for detecting the presence of objects (42) in a passenger compartment of a vehicle (43), wherein electromagnetic signals are radiated into the passenger compartment. The signals are reflected in accordance with at least one object property of at least one object (42) that is present in the passenger compartment. The reflected signals are received and are evaluated with regard to the at least one object property. The method is characterized in that the method is performed by a vehicle-to-X communication device (303) that communicates wirelessly. The invention further relates to a corresponding device.

Description

Method and device for detecting the presence of objects in a passenger compartment of a vehicle

The invention relates to a method for detecting the presence of objects in a passenger compartment of a vehicle according to the preamble of claim 1 and a device for detecting the presence of objects in a passenger compartment of a vehicle according to the preamble of claim 10.

It is already known in the prior art to provide motor vehicles with vehicle-to-X communication devices for message transmission as well as with different sensor devices for environment detection, such as e.g. with camera or radar devices. All of these devices are aligned with the environment outside the vehicle and are used in the context of driver assistance systems usually improve the vehicle safety, in particular the occupant safety. Likewise, in the prior art devices for detecting a seat occupancy in the vehicle, known as e.g. so-called seat mats. These too serve to improve occupant safety.

In this connection, DE 10 2006 050 214 A1 discloses a lane recognition method for assisting a driver when driving with a vehicle. In this case, a driving ^¬ web edge detection is first carried out, for example by means of infrared sensors, camera sensors or radar sensors. Based on the evaluation of the sensor signals according to features that represent the superficial Be ^¬ creation of the road and the roadside, there is a detection of a lane change. Is now recognized that the vehicle leaves the lane without the turn signal has been actuated, then a warning signal to the driver. The warning signal can be visual, acoustic or haptic. From DE 10 2007 048 809 AI a method for detecting obscured objects in traffic is known. The environment of a vehicle as well as the motion variables of the vehicle are detected by sensors. This information is communicated to the environment by means of vehicle-to-vehicle communication

Transfer vehicles. At the same time environmental and Bewegungsin ^¬ information recorded by the surrounding vehicles. The received information is used to extend an environment model. The thus he ^¬ panded environment model is updated by means of a display in the vehicle is reproduced and can be provided to one or more driver assistance systems. Thus, in the vehicle information about objects are available, which can not be detected by the vehicle sensors themselves. In DE 10 2008 016 659 AI, inter alia, a method for detecting the presence of the driver on the driver's seat by means of a seat covering mat is disclosed. Alternatively, the presence or the position of the vehicle driver can be detected by means of a camera or by means of an ultrasound system.

DE 10 2004 032 473 A1 describes an evaluation method and an evaluation device for a system for seat occupancy recognition. In this case, a vehicle seat is illuminated by means of an electro ^¬ magnetic wave field. The wave field can be both high frequency and low frequency. The driving ^¬ imaging seat has at several different locations on reflectors that reflect the wave field and modulating the reflected wave field at the same time. If a reflector is obscured, for example by a person who is on the ^

Seat is located, the corresponding reflector can not reflect the wave field. A receiver now receives the reflected wave fields and makes an assignment to the respective reflectors based on the included modulations. This not only allows a seat occupancy recognition per se, but also a recognition of the assumed position of a person on the seat.

A disadvantage of the methods and devices known from the prior art, however, is that for detection of seat occupancy within the vehicle to the outwardly directed sensor device additional sensor devices must be used, which causes additional manufacturing costs and thus cost.

The invention is therefore based on the object to propose a method which makes it possible to reduce the necessary according to the prior art sensor effort for detecting objects within the vehicle.

This object is achieved by the method for detecting the presence of objects in a passenger compartment of a vehicle according to claim 1. The invention relates to a method for presence detection of objects in a passenger compartment of a vehicle, wherein electromagnetic signals are radiated into the passenger compartment, said signals in accordance with at least one Whether ^¬ jekteigenschaft at least one object that is present in the passenger compartment reflected, and wherein the re ^¬ inflected signals are received and evaluated with respect to the at least one object property. The method is characterized by the fact that it is communicated by a wireless a running vehicle-to-X communication device.

This results in the advantage that no additional sensor system has to be used to detect the presence of objects in the passenger compartment of the vehicle, since instead a vehicle-to-X communication device that already exists in the vehicle and uses wireless communication is used. Indeed, as things stand, it is likely that in the near future new vehicles, at least within the European Union, will be fitted as standard with such a vehicle-to-X communication device.

Since a vehicle-to-X-communication device typically by means of transmitting and radiating and receiving electromagnetic signals performs its primary task of the wireless communication, are thus also no wändigen on ^¬ modifications to the vehicle-to-X-communication device necessary to enable them to carry out the method according to the invention. The signals used for wireless communication can also be used without modification for the presence detection of objects in the passenger compartment as well as for communication. According to the invention, the term object property means any property of an object which shapes the reflected signal. This can be, for example, a surface texture of the object which characterizes the intensity of the reflected signal, a position of the object which, for example, characterizes a phase behavior of the reflected signals and thus an interference behavior, or else a movement behavior which, for example, shapes a frequency shift of the reflected signals. These object properties are thus present as information in the reflected signal and allow a corresponding evaluation Presence detection of the objects having the object properties in the passenger compartment.

The objects according to the invention are preferred

However, it may also be inanimate objects, e.g. Luggage, act.

Advantageously, the objects are associated with a vehicle seat ^¬. This simplifies the presence detection of objects in the passenger compartment in so far as these are expected to firmly pre ^¬ abandoned positions and thus can be searched.

Furthermore, it is provided that the messages contained in the received signals are at least partially evaluated by the vehicle-to-X communication device, in particular if they have been sent by other vehicle-to-X communication devices. Thus, the vehicle-to-X communication device continues to be used for its primary task.

Preferably, it is provided that the at least one Whether ^¬ jekteigenschaft is determined from a Doppler frequency of the reflected signals. The Doppler frequency is generated by a movement of the object, which reflects the signal and describes a change in the frequency or wavelength of the reflected signal relative to the radiated signal. It has been found that the evaluation of the Doppler frequency enables a robust, reliable and accurate presence detection of different objects in the passenger compartment.

According to a further preferred embodiment of the invention, it is provided that the Doppler frequency by means of a low-pass filter, in particular by means of a digital low-pass filter, is filtered. This causes - depending on the design of the low-pass filter - Doppler frequencies that exceed a certain cutoff frequency, filtered and not used for further evaluation. Thus, irrelevant frequency ranges of the Dopp ^¬ lerfrequenzen can be sorted out before the evaluation for the inventive method, which allows a reduction of the processing power required for the evaluation. This in turn allows the use of less powerful and thus less expensive computing modules. Thus, the evaluation of the Doppler frequencies or of the reflected signals with respect to the object properties can be carried out very efficiently by a computing module which is present in any case in the vehicle-to-X communication device. It can therefore be dispensed with an additional computing module or a replacement of the already existing computing module by a more powerful computing module.

It is preferably provided that the at least one object property describes a movement behavior. The term physical activity is to be interpreted broadly in accordance with the invention, and describes not only a so-called "Gesti ^¬ a voice to" persons or a substantial immobility of luggage, but also actually any kind of movement, the movement behavior of an object -. Regardless of whether It is particularly well-suited for detecting the presence of this object in the passenger compartment, since the movement behavior of an object differs significantly from the movement behavior of an unoccupied vehicle seat by forces and vibrations acting on the item of luggage during the journey, recognizable from that of an unoccupied vehicle seat Pulse beat of a human by means of the method according to the invention possible, since even the beating of the human heart causes detectable by the method according to the invention movement on the body surface. Thus, based on the movement behavior so can be made a reliable statement about whether objects are present in the passenger compartment. The detection of the pulse rate of a person has proven be ^¬ Sonder readily be carried out by means of a signal wavelength of about 6 GHz. This signal wavelength corresponds essentially to the wavelength used for WLAN communication according to IEEE 802.11p.

Particularly preferably, it is provided that BEWE ^¬ supply behavior will be based on a distinction between living and nonliving Obj ects. Since, apart from comparatively extensive movements, such as arm and leg movements of persons, as already described, even the detection of the pulse beat of a human is possible, a reliable distinction between living and inanimate objects can be made. This information can be used, for example, in case of accident of the vehicle of the existing security systems, for example, to adjust the ignition settings of air impact bags inside the passenger cell or when issuing an automated emergency call, which contains the number of vehicle occupants.

In particular, it is particularly preferred that a ^{sub-¬-making} is done by children or adolescents and adults. This can happen, for example, through the characteristic behavioral behavior of children or adolescents towards adults, as children or adolescents are generally much more restless than adults. Also possible is a distinction by Doppler frequency components of the reflected signal, which describe vibrations of the vehicle seat on ₀

which the person is. Since a child covers only a smaller area of the vehicle seat than an adult, the reflected signal is comparatively more strongly influenced by the vibrations of the vehicle seat. A combination of both differentiation options is preferred.

In addition, it is preferred that the movement behavior of a vehicle driver is monitored with regard to decreasing intensity of movement. A decreasing intensity of movement can be recognized, for example, by a decreasing pulse rate or overall by a decrease in the embossing of the reflected signal by Doppler frequencies. This results in the advantage that conclusions about the condition of the vehicle ^¬ leader are possible, in particular on its driving ability, which often decreases when covering longer distances and thus represents a potential hazard. Upon detection of the

Falling below a perceived as critical intensity of movement and associated driving ability of the driver this can thus be warned and pointed out that he is in a critical condition in terms of driving ability. The awakening of the driver from a so-called. Seconds sleep is possible. The driver is to be understood as an object within the meaning of the invention. It is expedient that the movement behavior of several objects is monitored separately. This results in the advantage that a plurality of different objects not only recognized as present, but also can be distinguished beyond. This information can be used, for example, for security systems.

It is provided that, for a given time interval, a transmission power of the signal is set in such a way that the signal is a wireless signal which takes place outside the passenger compartment _

 y

Communication is not affected. This initially results in the advantage that the method according to the invention can be carried out decoupled from a communication method that is taking place, it being irrelevant whether the vehicle-to-X communication device of the invention executes the method

 Vehicle is involved in the communication outside the passenger compartment or not. Thus, the inventive method is very flexible. Furthermore, there is the advantage that the objects in the vehicle are only exposed to a reduced radiation power, which does not bring any detectable changes in terms of guaranteed in any case health safety of the inventive method, but is usually very positively received psychologically.

In particular, it is provided that the signal is radiated free of specifications of a communication protocol of the vehicle-to-X communication device. Since the transmission power of the signal is set such that the signal does not affect a wireless communication taking place outside the passenger compartment, no consideration has to be given to any communication protocols used. Thus, for example, a signal may be emitted that continues uninterruptedly over a period of one or more seconds. This further improves the reliability and accuracy of the presence detection according to the invention.

Furthermore, it is preferred that by means of the method when the vehicle ignition is switched off, the passenger compartment is monitored for movements. This results in the advantage that the presence of objects within the passenger compartment is recognized even when the vehicle ignition is switched off. This information can be used for example for providing a Alarmfunktio ^¬ ality to an unauthorized intrusion into the Vehicle to recognize. As a result of the unauthorized intrusion, for example, the delivery of loud warning tones and optical signals can be triggered. Under certain circumstances, it may be useful to tie the triggering of such an alarm functionality to other criteria, such as the state of a central locking.

The invention further relates to a device for detecting the presence of objects in a passenger compartment of a vehicle, comprising a transceiver, a plurality of antenna elements and evaluation means, wherein the transceiver emits electromagnetic signals into the passenger compartment by means of the plurality of antenna elements, wherein the signals in accordance with at least one object property at least one object that is present in the passenger compartment, and wherein the transceiver receives the reflected signals by means of the plurality of antenna elements and on to the evaluation means, which evaluate the reflected signals with respect to the at least one object property. The inventive device is characterized in that the transceiver is a wireless communicating vehicle-to-X-communication device and a main radiation direction of at least one antenna element comprises in the driving ^¬ passenger cell.

This results in the already described advantage that a vehicle-to-X communication device, which is already present in the vehicle, is used without additional production and expense for the presence detection of objects in the passenger compartment of the vehicle. By a main radiation direction of at least one antenna member in the passenger compartment, there is the further advantage that the passenger compartment, so the space to be monitored, in which a Presence detection is to take place, comparatively well with the signals is illuminated.

The device according to the invention thus offers a cost-effective and reliable alternative to the so-called seat-covering mats which are frequently used in the prior art. Also, the ultrasonic devices used in the prior art for seat occupancy detection can be advantageously replaced by the device according to the invention, since the device according to the invention is not only inexpensive, but also no adverse effects on pets such. Has dogs that can be very sensitive to ultrasound.

The main emission direction of an antenna element is dependent on the geometry of the respective antenna element. The together ^¬ link between geometry and the main emission direction of an antenna element is common knowledge.

It is provided that at least one antenna element is arranged on or in a windshield of the vehicle and / or that at least one antenna element is arranged on or in a vehicle roof of the passenger compartment. An arrangement on or in the windshield leads to the advantage that the signals can be radiated both comparatively well forward from the vehicle and into the passenger compartment. Thus, ie both good communication capability as well as to ^¬ reliable presence detection are ensured particular allows such an arrangement a particularly simple presence detection of objects on the driver's seat and the front passenger seat, since these can be illuminated immediately in such an arrangement with the signals. Thus, a possibly necessary switching operation is unnecessary between antenna elements used for communication and for carrying out the method according to the invention, since a on or in one Windscreen arranged antenna member both requirements ^¬ ments simultaneously meet.

The arrangement on the windshield may be e.g. done by gluing. In an arrangement in the windshield, the antenna member may e.g. already integrated in the manufacture of the windshield and have an electrical interface to its contact. Particularly suitable for the arrangement on or in the windshield are so-called antenna patches, which are formed substantially two-dimensionally and have two opposite main emission directions, respectively

away from the two-dimensional surface.

An arrangement on or in the vehicle roof, however, allows both a circular radiating around the vehicle, whereby a comparatively large space area is covered for communication purposes, as well as a radiating from above in the

Passenger compartment. However, the use of antenna patches in this case is less suitable since, due to their geometry, they have main emission directions that can not point simultaneously into the passenger compartment and circularly into the vehicle environment around the vehicle. The arrangement on or in the vehicle roof also offers the advantage that an antenna element can be arranged above each vehicle seat, so that each vehicle seat can be individually illuminated. Thus, e.g. Shutting off a vehicle ventilation system is avoided as long as people are in the vehicle, regardless of which vehicle seat they are on.

The monitoring of individual vehicle seats offers, in addition to a presence detection for each individual vehicle seat, the additional possibility of calculating the number of persons present as being present. knew objects to deduce a statement whether there is a clear view to the rear for the driver.

An arrangement on the vehicle roof is preferably carried out at the home inner side of the vehicle roof, so as better property ^¬ comprehensive detection of objects in the passenger compartment is possible.

An arrangement in the vehicle roof is understood to mean an arrangement penetrating the vehicle roof which partially positions the antenna element both on the outside and on the inside of the vehicle roof.

In addition, it is provided that at least one antenna member is disposed completely within the passenger compartment. This results in the advantage that the passenger compartment is relatively well and completely illuminated by this antenna element, since in this case all Hauptabstrahlrichtungen have in the passenger compartment. It is preferred that the evaluation means determine a Doppler frequency from the reflected signals. As already described, the Doppler frequency of the reflected signals enables a robust, reliable and accurate attendance ^¬ recognition of different objects in the passenger compartment. For example, the Doppler frequency may be determined from the Doppler phases if the signals are too short in time to fully cover a signal period. The duration of the signals is mainly characterized by the used Kom ^¬ tion protocol.

In addition, it is preferred that the device uses a first number of antenna elements exclusively for receiving and a second number of antenna elements are used exclusively for emitting, wherein in particular the main Have beam directions of the first number of antenna members in the passenger compartment. This results in the advantage that, for example, a single antenna element, which is located approximately in the windshield, can be used for emitting the signals, while two independent antenna elements are used exclusively for receiving the reflected signals, wherein one of the antenna elements used exclusively for receiving For example, the driver and the other is assigned to the passenger. This allows a simple way of simultaneous detection and observation of both the driver and the passenger without affecting or interrupting communications. Such a method by means of spatially separated transmitting and receiving antenna elements is also generally known as a bistatic method.

In particular, it is preferred that the antenna elements of the first number used exclusively for reception, e.g. be shadowed by means of partitions so that they only a given section of the

Passenger cell can see or receive only reflected signals from the predetermined section of the passenger compartment. This cutout preferably comprises a single vehicle seat. Thus, a trouble-free and reliable monitoring of individual vehicle seats is possible.

Furthermore, it is particularly preferred that the device controls the antenna elements of the first number with a time offset from one another and / or controls the antenna elements of the second number with a time offset from one another. Thus, not all the antenna elements of the first and the second number are thus activated simultaneously. This has the advantage that, by appropriate control of only one assigned to the each ^¬ weiligen antenna element section of the passenger cell is monitored. Thus, the reception of interference signals from another section of the passenger compartment is completely avoided. Thereby, the inventive method to be more reliable and more robust ^¬.

Particularly preferably, it is provided that mutually associated antenna elements of the first number and the second number are controlled synchronized. An ^¬ mutually associated antenna members are antenna elements, which together is responsible to monitor a section of the passenger compartment. Thus, mutually associated antenna elements are, for example, two antenna elements, of which the antenna element of the second number transmits a signal which is received by the associated antenna element of the first number. This has the advantage that presence detection becomes even less susceptible to interference and even more robust.

It is also advantageous that the apparatus executing the method according OF INVENTION ^¬ dung. This results in the advantages already described.

The vehicle-to-X communication device expediently communicates by means of at least one of the following types of communication:

 WLAN communication, in particular according to IEEE 802.11p,

- WiFi Direct Communication,

 - ISM communication (Industrial, Scientific, Medical

 Band), in particular via a radio-compatible closing device,

 - Bluetooth communication,

 - ZigBee communication,

 - UWB communication (Ultra Wide Band),

- WiMax communication (Worldwide Interoperability for Microwave ,,

 1 b

Access),

 - remote keyless entry communication,

 Mobile communication, in particular GSM, GPRS, EDGE,

 - UMTS communication,

 - LTE communication and

 - Infrared communication.

The mobile-based communication means are assigned to special ^¬ an automatic emergency call module. Depending on the type of communication used different types of electronic signals are therefore used for the inventive method.

When using a two-channel communication, such as WLAN communication according to IEEE 802.11p, a first channel may preferably be used continuously as a so-called control channel, which is reserved exclusively for communication purposes for vehicle safety devices. A second channel can then be switched between two total of two different so-called service channels. In the context of this switching over, the second channel can also be used exclusively for the method according to the invention for a predeterminable period of time without any communication taking place. Preferably, this is at least one exclusively used for emitting antenna member inside the passenger cell provided which emits the signals with a reduced transmission power and whose Hauptabstrahlrichtungen all have in the passenger compartment. Further preferred embodiments will become apparent from the subclaims and the following description of an embodiment with reference to figures. Show it

Fig. 1 shows an exemplary structure of an inventive

 Contraption,

Fig. 2 shows schematically an attachment of the invention

 3 shows a further exemplary construction of the device according to the invention, FIG.

Fig. 4 is a equipped with the apparatus of the invention motor vehicle and

Fig. 5 by way of example two specific Doppler frequencies that allow determination of the underlying movement behavior. 1 shows an exemplary construction of a device according to the invention for detecting the presence of objects in a passenger compartment of a vehicle. The apparatus comprises Sen ^¬ demodul 100, antenna elements 101 and 102, receiving module 103, modulator 106 containing for generating a vehicle-to-X message and radiated signal into digital form,

Digital-to-analog converter 107 for converting the digital signal into an analog signal, analog-to-digital converter 108 for converting a received signal into digital form, demodulator 109 for demodulating the received signal in order to process it further and evaluation means 110 for determining a Doppler frequency from the received signal and for analyzing a movement behavior of present objects from the Doppler frequency. Antenna member 101 is used exclusively for emitting signals, while antenna member 102 exclusively is used to receive signals. Thus, a simultaneous emitting and receiving is possible. Alternatively, a simultaneous radiation and reception could be made possible by means of a so-called circulator or a so-called bidirectional coupler. The exemplary device radiates in each case alternating in time on a first and a third WLAN channel in the context of a WLAN communication according to 802.11p, while a second, the first channel separating from the third channel, remains unused. Via communication block 104, an information connection of different driver assistance systems 105 by means of modulator 106 or demodulator 107 is ensured. Thus, driver assistance systems 105 may trigger the transmission of signals and process received signals. Reception module 103 comprises, for example, clock 113, which specifies a clock frequency of 5.9 GHz, which corresponds to the base frequency of the WLAN 802.11p used for communication by the vehicle-to-X communication device. An identical clock generator is also included in the transmission module 100, which however is not shown in FIG. 1 for reasons of ^clarity . Furthermore, receiving module 103 comprises delays 114, which delays the clock signal output by clock 113 on the signal path to mixer 115 which is likewise encompassed by receiving module 103 in comparison with mixer 116 by 90 ° over a matched line length. This causes a splitting of the received signal into two mutually phase-shifted portions. Thus, a phase ambiguity of the Doppler frequency contained in the received signals can be resolved since it is now treatable as a complex number in the complex number plane rather than a real number on a one-dimensional number string and thus has an additional dimension. Mixers 115 and 116 mix the mutually out-of-phase components with the clock signal from clock 113. Following each of mixers 115 and 116 are low pass filters 117 and 118 which filter the high frequency components of the received signals to produce a subsequent processing. simplify and speed up the process. About shunts 119 and 120, both signal parts are continued after the digitization of evaluation 110. Evaluation means 110 determine in a first step by frequency adjustment of the emitted signals with the received signals one in the

Signals contained Doppler frequency and in a second step, a movement behavior, which is based on the Doppler frequency. In accordance with a request received via data line 121, a frequency change of transmission module 100, the transmission of a communication packet without information content or a change or deactivation of the communication protocol used can also be triggered.

2 shows two-seat motor vehicle 21 with a device according to the invention attached thereto. Motor vehicle 21 has a vehicle roof 22 on which antenna members 23, 24 and 25 are mounted. Antenna member 23 is an antenna member used for communication purposes. Dement ^¬ speaking, the orientation of the main ^emission directions of antenna member 23 is such that is emitted mainly in the plane of the drawing. In this plane has antenna element

23 also has the best reception characteristics. Antenna members 24 and 25 are so-called antenna patches, which are substantially two-dimensional and are arranged on the inside of the vehicle roof. Antenna members 24 and 25 thus have their main emission directions in and out of the plane of the drawing. Antenna member 24 is disposed above the driver's seat, arranged antenna member 25 above the passenger seat. All three antenna elements are capable of being used simultaneously for both radiating and receiving by means of a circulator (not shown). By means of switchable connection 26 are antenna links

24 and 25 controlled to illuminate the sections of the passenger compartment assigned to them and to detect objects present. At temporally short intervals antenna members 24 and 25 are now driven to determine the occupancy in the passenger compartment. At the same time, the movement behavior of the objects present is determined and, in particular, the movement intensity of the driver is monitored in order to monitor his driving ability. Likewise, entry and exit into or out of the vehicle and possibly unauthorized intrusion into the vehicle are monitored. In Fig. 3 is a schematic view of a possible structure of the device according to the invention. Illustrated are evaluation means 301 with processor 302 for determining a Doppler frequency and the movement behavior of an object on which the Doppler frequency is based, vehicle-to-X communication device 303 with transmission module 304,

Receiving module 305 and switching units 306, 307, 308 and 309 to ^¬ antenna elements 310a, 310b, 311a, 311b, 312a and 312b ^¬ steer. Antenna members 310a and 310b exclusively communicating with other communications devices, said signals are radiated from 310a by means ^¬ antenna element and are collected by the antenna member 310b signals emp ^¬ serve, for example according to. Antenna links 311a and 311b are associated with the driver's seat of a vehicle, not shown, and serve to detect the presence of the vehicle driver. Signals are radiated by means of antenna element 311a, and the reflected signals are received by means of antenna element 311b. Antenna links 312a and 312b are associated with the passenger seat and serve to detect presence of a passenger. Signals are radiated by means of antenna element 312a and the reflected signals are received by means of antenna element 312b. Switching units 306, 307, 308 and 309 allow a time-delayed driving of the individual antenna elements. Evaluation means 301 are connected via HF line 313 to vehicle-to-X communication device 303 and are connected via data line 314 with a user interface. cutting parts, which may emit a warning tone, for example, to warn the driver on detection of diminishing driving ability due to fatigue. FIG. 4 shows vehicle 43 in which driver 42 is located. Vehicle 43 is equipped with the device according to the invention. On the roof of the vehicle 43 is arranged at ^¬ antenna member 44, which is used exclusively for communi cation with ^¬ other vehicle-to-X-communication devices. In the windshield of vehicle 43 antenna patch 41 is also arranged, which is both for communication with others

Vehicle-to-X communication devices as well as for the presence detection of objects in the driver's seat is used. Namely, the antenna member 41 has a main radiation direction on the driver's seat, illuminates it with electromagnetic signals, and detects a Doppler frequency contained in the reflected signals. In FIG. 5, for example, two specific Doppler frequencies are shown 51 and 52, the determination of the underlying each ^¬ lying movement behavior of a vehicle driver ermögli ^¬ chen. As can be seen, is shown in Fig. 5a Doppler frequency ^¬ 51 comparatively weak. It has only a small amplitude with a period of about 2 Hz. Based on the low amplitude is detected that the Fahr ^¬ zeugführer behaves essentially quiet. The period of 2 Hz is the driver's pulse, which corresponds to 120 beats per minute. Based on the high pulse is thus recognized that the driver despite his quiet movement behavior is alert and attentive.

In contrast, Doppler frequency 52 shown in FIG. 5 b has such a high amplitude that the pulse of the vehicle driver it is no longer recognizable. The high amplitude is triggered by an intensive movement behavior of the driver. The measured period of about 10 Hz is generated by the under ^¬ different movements of the driver. In this case, it is recognized from the high amplitude that the driving ^¬ convincing leader awake and alert.

Claims

claims

1. A method for detecting the presence of obj ekten (42) in a passenger compartment of a vehicle (43), in which electromagnetic signals are radiated into the passenger compartment, wherein the signals in accordance with at least one object property min ^¬ least one object (42), the is present in the passenger compartment, are reflected, and wherein the reflected signals are received and evaluated with regard to the at least one object property;

characterized in that the method is performed by a wirelessly communicating vehicle-to-X communication device (303).

2. The method according to claim 1,

characterized in that the at least one Objektei ^¬ genschaft from a Doppler frequency (51, 52) of the reflected signals is determined.

3. The method according to at least one of claims 1 and 2, characterized in that the at least one Objekti ^¬ genschaft describes a movement behavior.

4. The method according to claim 3,

characterized in that based on the movement behavior, a distinction of living and inanimate objects (42).

5. The method according to at least one of claims 3 and 4, characterized in that the movement behavior of a

Driver (42) is monitored in terms of decreasing intensity of movement.

6. The method according to at least one of claims 3 to 5, characterized in that the movement behavior of several objects (42) is monitored separately.

7. The method according to at least one of claims 1 to 6, characterized in that for a given time interval, a transmission power of the signal is set such that the signal does not affect a taking place outside the passenger compartment wireless communication.

8. The method according to claim 7,

characterized in that the signal is radiated free of specifications of a communication protocol of the vehicle-to-X communication device (303).

9. The method according to at least one of claims 1 to 8, characterized in that the passenger compartment is monitored for movements by means of the method at off ^¬ Asked vehicle ^ignition .

10. A device for detecting the presence of objects in a passenger compartment of a vehicle (43), comprising a transmitter ^¬ receiver (303), a plurality of antenna elements (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) as well as from ^¬ values medium (110, 301), wherein the transceiver (303) via the plurality of antenna elements (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) electromagnetic signals in the Passenger cell radiates, wherein the signals in accordance with at least one object property of at least one obj ekts (43), which is present in the passenger compartment, reflected and wherein the transceiver (303) receives the reflected signals by means of the plurality of antenna elements and the evaluation means (110, 301), which evaluate the reflected signals with regard to the at least one object property, characterized in that the transceiver (303) is a wirelessly communicating vehicle-to-X communication device (303) and one

 Main emission direction of at least one antenna member (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) points in the passenger compartment.

11. The device according to claim 10,

characterized in that at least one antenna member (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) is disposed on or in a windshield (41) of the vehicle (43) and / or that at least an antenna member (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) is disposed on or in a vehicle roof of the passenger compartment.

12. The device according to at least one of claims 10 and 11, characterized in that at least one antenna member (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) is disposed completely within the passenger compartment.

13. The device according to at least one of claims 10 to 12, characterized in that the evaluation means (110, 301) from the reflected signals determine a Doppler frequency (51, 52).

14. The device according to at least one of claims 10 to 13, characterized in that the device uses a first number of antenna members (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) exclusively for receiving and a second number of antenna elements (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) are used exclusively for radiating, wherein in particular the main radiating elements have the first number of antenna members (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) in the passenger compartment.

15. Device according to claim 14,

characterized in that the device controls the antenna elements (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) of the first number with a time offset from one another and / or the antenna elements (101, 102, 23, 24, 25, 310a, 310b, 311a, 311b, 312a, 312b) of the second number with a time offset from one another.

16. The device according to at least one of claims 10 to 15, characterized in that the device performs a method according to any one of claims 1 to 9.