DE19915097A1 - Device and method for in particular mobile data acquisition - Google Patents

Abstract

The invention relates to a device (MC) and to a method especially for the mobile data collection with at least one input interface (S1..S4) for supplying input data (I1..I4), especially data of a motor vehicle (F1..Fn), a machine etc. Said device is provided with a signal processing unit (16) that can be coupled with the input interface (S1..S4) and that is used to process the signals of the input data (I1..I4) supplied via the input interface(s) (I1..I4). It is further provided with an output interface (SA) for supplying output data (17) of the signal processing unit (16) to the transceiver device (5) for transmitting the output data (17) to a central unit (15). The aim of the invention is to provide a simplified means for the automated and systematic collection of data for the collection of process data, for issuing an alarm signal etc. To this end, the signal processing unit (16) is provided with means (A, L, D) for recording and evaluating determined input data (I1..I4) at determined times.

Description

The invention relates to a device for mo in particular bile data acquisition with at least one input cut place for the supply of input signals, in particular of Operating data of a vehicle, a machine etc., with a signal processing that can be coupled to the input interface device for signal processing via the on input signals.

The invention further relates to a method for mobile data acquisition from at least one input Interface input signals, especially from Operating data of a vehicle, a machine etc., in which the input interface with signal processing direction for signal processing via the input cut place coupled input signals is coupled.

Such a device comes for example in vehicles conditions, for example passenger cars, commercial vehicles, construction machines, agricultural machines etc. are used. Often there is a systematic recording of operating data and monitoring of vehicles is desirable.

Such a device is known from GB 2,194,119 A1. The data acquisition device contains input sensors the status or certain security conditions record. In addition, there is signal processing direction provided that creates a status report that the Identity and location of the data collection device as well as the contains the respective operating data. With the data acquisition pre direction, a dialer and a radio telephone are connected, which transmits the status report to a remote station telt.  

The invention has for its object a device and a method for in particular mobile data acquisition admit that easily automated and systematic data collection and forwarding from Pro data, alarm messages etc.

This object is achieved by a device for in particular mobile data acquisition with at least one input interface place for the supply of input signals in particular from Operating data of a vehicle, a machine etc. solved, with a signal that can be coupled to the input interface Processing device for signal processing of the Input interface (s) input signals and Recordable data of the input signals predeterminable times and with an output interface for feeding in from the input signals in the signal ver Work device derived according to predetermined rules Output data of the signal processing device to a Signal processing device for processing the output data to a transmitter that can be coupled to the device Receiving unit for automatic and / or on request directed transmission of the output data to the one control center and / or to a predetermined recipient.

This task is accomplished by a method especially for mobi len data acquisition of at least one input cut place input signals supplied, in particular from Be drive data of a vehicle, a machine etc. solved which the input interface with a signal processing device for signal processing via the input Interface input signals is coupled, at the predefinable data of the input signals at predefinable time points recorded by the signal processing device and from the input signals in the signal processing direction based on predefinable rules be connected to one with the signal processing device  couplable transceiver unit automatically and / or on ask a head office and / or a predetermined address be forwarded.

The invention is based on the knowledge that the Use of a mobile data acquisition device, in particular re in the area of complex construction machinery, construction vehicles as well Commercial vehicles, etc. systematic data acquisition gen which can lead to a higher availability of the respective vehicles etc. leads. For this, the data provider detection device via the input interface each input required for evaluation and diagnosis signals fed. In the signal processing device of Data acquisition device, this input data of the Input signals either in the operation of the respective vehicle or even when the vehicle is at a standstill according to beforehand rules stored in the signal processing device are evaluated and either automatic or on ask a central office, for example, about the Receiving unit to a specific addressee or to the Headquarters forwarded. For example, for a be The central vehicle fleet responsible contains a comprehensive overview of the respective machine conditions and to the measured values of the vehicles, which means, for example, early technical failures in relation to operational safety and availability of the respective vehicle can be recognized can. In addition, the respective Optimize service intervals for each vehicle. The required for the evaluation of the respective input data Chen rules are ge in the signal processing device saves and can be customized to each Vehicle etc. and the individual conditions of use be adjusted.

A simple and inexpensive way to project tion of the data acquisition device can thereby be achieved that the device has at least one writable  Memory for storing an operating system of the device device and / or the specifiable rules, the for memory data specific to the memory via the transmission Receiver unit can be loaded remotely.

Effective data processing through signal processing device regardless of the respective data format of the Input signals can be achieved in that the Vorrich device between the input interface and signal processing device arranged data converter, which for Equalization of input signals and ready provision of a uniform data format for the input interface (s) fed input signals.

An additional preparation of the input data regarding the specific addresses can be done in such a way that the Device one between data converter and input cut position (s) provided address assignment unit, the to implement the source-specific addresses of the input Signals provided on the address format of the data converter is.

A data logging and analysis similar to an oscilloscope can be made possible by the fact that the signal processing device has a data analysis unit for opening drawing of selected input signals to predefinable ones At times is provided, the specification of recording rules for the short-term observation of information derived from the input signals. An energy-saving operation of the device in the mobile Deployment is vital, it can aims to have the device operated by a motor benen mobile vehicle is installed and a connection direction for connection to the supply voltage of the vehicle Stuff has that the device means for detection min at least a first operating state "generator the supplier supply voltage source in operation "and a second operation  state "generator of the supply voltage source not in Operation ", an Un The work of the data analysis unit is interrupted. A Alarm monitoring and long-term data acquisition can be done if necessary continue to run.

User-friendly monitoring and targeted Diagnosis based on the mobile data collection device processing processable input signals especially in the sense of egg Long-term evaluation can be done in such a way that the Signal processing device a data processing unit for recording from the input signals according to the specified Ren rules derived information data and that the Device a first memory for storing the rules the data processing unit.

The power management of the data acquisition device is there further improved by the fact that the first memory two stor Has areas, a first memory area Rules for the operating state "generator of the supply voltage source in operation "and a second memory area the rules for the operating state "generator of the supplier supply voltage source not in operation ".

An alarm function of the data acquisition device can be there be generated by the signal processing device an alarm unit for monitoring from the input signals len information that can be derived according to predefinable alarm rules ten has that the device for a second memory Storage of the rules of the alarm unit has.

An observation of the alarms that have taken place, for example for statistical evaluations can be secured in the way be that the device an alarm archive for on alarms.  

Observing the total in the data acquisition device and can also be queried via an online connection output signals and the information derived from them thereby ensuring that the signal processing device an observation unit for direct observation of Input signals and / or from the input signals has conductive information data.

An additional intervention in terms of operating and monitoring eighth is achieved in that the observation unit as Control and monitoring unit also for direct operation of operating states of a coupled with the device Vehicle can be fed via the input / output interface (s) Has control signals.

The applications of the data acquisition device and the processing of the input data can still be done times enlarged or expanded that the device can be coupled with a GPS receiver.

Realization of the data acquisition also under multi-groove Components can be particularly advantageous and costly save in such a way that the device in one Car radio receiver and / or in a car radio receiver ger / integrated mobile phone device combination or ge is coupled.

In the following the invention with reference to the in the figures illustrated embodiments described and he purifies.

Show it:

Fig. 1 is a block diagram of an embodiment of ei nes overall system for mobile data acquisition,

Fig. 2 is a diagram for coarse structure of the Datenerfas sungsvorrichtung,

Fig. 3 is a schematic representation of an embodiment of a data logging apparatus,

Fig. 4 shows an overview of exemplary Projektierungsda th of data logging apparatus,

Fig. 5 shows an example of a mask for setting rules of a data analysis unit.

Fig. 1 is a block diagram showing an embodiment of an overall system for mobile data acquisition. The data acquisition system includes vehicles F1. .Fn a vehicle fleet. The vehicles F1. .Fn are each equipped with a data acquisition device MC, the data acquisition device MC and the interaction with other components of the respective vehicle F1. .Fn is shown only with reference to vehicle F1. The data acquisition device MC has input interfaces S1. .S4 on, via the respective input signals I1. .I4 from data sources Q1. .Q4 who fed. The first interface S1 is provided, for example, for processing input signals of a communication bus, as is used in vehicles as a so-called CAN bus (CAN = Controller Area Network). Operating data for engine temperature, water temperature, oil pressure, oil temperature, battery voltage etc. are transmitted via such a data bus. The second interface S2 is designed, for example, as a serial interface, for example for connecting a keyboard etc., while the third interface S3 is provided, for example as a so-called "on board I / O" interface, for example for connecting sensors, sensors, etc. The fourth interface S4 is used for the optional connection of a GPS module (GPS = Global Positioning System). The data acquisition device MC has an output interface SA, which is connected to a transceiver 5 , for example a GSM module (GSM = Global System for Mobile Communication ) is coupled. The GSM module 5 is connected to a transceiver antenna 6 . The driving tool F1 can via a radio interface 9 between the antenna 6 of the data acquisition device MC and an antenna 11 of a base station 10 a. .10n establish a bidirectional data connection. The base stations 10 a. .10n of a GSM mobile radio network N are connected to a network operator 13 of the mobile radio network N. The operator 13 of the mobile radio network N has a connection 14 to a center 15 . Alternatively or in addition, a further data connection as a mobile data connection 16 is possible via a further base station 17 between a receiver E and the operator 13 as a mobile data connection 12 . A computer 20 with a data processing device 22 , monitor 21 and keyboard 23 serves as a human-machine interface for communication between the control center 15 and the data acquisition device MC.

Fig. 1 shows the embedding of the data constitution MC apparatus within a system for monitoring and diagnosis of vehicles F1. .Fn. Instead of the driving test shown in Fig. 1 F1. Other mobile and stationary vehicles and machines, for example construction vehicles, cranes, containers, rail vehicles, etc., can also be integrated within such a system. As will be explained in detail in connection with FIG. 3, the data acquisition device MC draws certain input signals I1. .I4 over a long period of time. For example, signals indicating the operational safety of the vehicle F1. .Fn relate, such as water temperature, oil temperature, cooling temperature of a refrigerated vehicle, etc., to be recorded at specific times in accordance with the rules stored in the data acquisition device MC. The signals recorded in this way can then be transmitted via the output interface either to the control center 15 or to the request of another receiver E via the output interface SA and the associated radio transceiver 5 to the control center 15 and / or the receiver E. . As a result, F1 can, for example, in the event of a malfunction. .Fn an effective fault diagnosis. In addition, there is the possibility of certain input signals I1 in the data acquisition device MC. .I4 started or stopped over a short period of time, for example by trigger events, also to be recorded and so to keep up to date machine and vehicle conditions based on a very current display and to initiate appropriate maintenance or repair measures, etc. The recording of signals over a short period of time can also take place, for example, in the form of a direct dialog connection between the control center 15 and the data acquisition device MC via an online connection in the form of the air interface 9 . The rules in the data acquisition device MC can be designed in such a way that an automatic alarm message can also occur when certain malfunctions occur, for example limit value violations. On the basis of the location data supplied via the GPS data source Q4, the data acquisition device MC can also transmit location data to the control center. On the one hand, this results in theft monitoring and, on the other hand, a clear fleet management of the vehicles of a vehicle fleet F1 to be recorded from the control center 15 . .Fn done. In addition, a voice connection between the driver of the vehicle F1 and the control center 15 is also possible via the radio link 9 between the control center 15 and the vehicle F1, without a separate radio transceiver being required for this. Furthermore, for example, in the event of an error, a notebook, etc., can also be connected on site via the interface 52 , and the recorded signals can thus be evaluated on site for an error determination. An optimal representation of the information transmitted from the data acquisition device MC to the control center 15 is made possible by the fact that a software package is installed in the computer device 22 , which is based, for example, on the operating and monitoring system from Siemens WinCC or on operating systems such as Windows . This also optimizes management, for example the incoming alarm messages. Special information for vehicles F1 can also be obtained from the head office. .Fn, for example, traffic radio, data and / or order data, etc., can be transmitted in a vehicle-specific or fleet-specific manner. The rules in the data acquisition device MC for acquisition and transmission of input signal data 1 a. .4a to the control center are stored in the data acquisition device MC in such a way that the rules can be downloaded from the control center 15 to the data acquisition device MC via the air interface 9 .

FIG. 2 shows an overview of the rough structure of a data acquisition device, this structure also being explained in more detail in connection with the more detailed basic illustration of FIG. 3.

Fig. 2 shows a schematic diagram for the data acquisition and data processing of a data acquisition device MC. As has already been explained in principle in connection with FIG. 1, the data acquisition device MC has input interfaces S1. .S4 on. The first interface S1 is designed, for example, as a CAN interface (CAN = Controller Area Network). The second interface S2 is formed in the embodiment shown in FIG. 3 as a serial interface, for example for connecting a keyboard, while the third interface S3 is designed as a so-called onboard input-output interface, for example for connecting sensors, sensors, etc. is. The fourth interface S4 is used to connect the data of a GPS module (GPS = Global Positioning System). The via the interfaces S1. .S4 input signals I1. .I4 who forwards via an address assignment unit A2 and a data converter EA to a signal processing device 1 . The signal processing device 1 has an output interface SA, via which output signals 18 are forwarded to a communication driver KT, for example a GSM driver. The Signalververarbeitungvor direction 16 contains means A, L, D, M for recording and moni toring of predetermined input signals I1. .I4 at predefinable times. The means L, A, D, M consist in particular of a data analysis unit D which is used to record selected input signals I1. .I4 is provided at predetermined times, the specification of the recording rules from the center for short-term observation of from the input signals 1 a. .4a derivable information takes place. The corresponding rules are stored in a data analyzer rule interpreter DR. A connection D1 enables the rules stored in the memory DR to be downloaded via the output interface SA. The recording of the data signals d ascertained with the aid of the data analysis unit D is carried out with the aid of the recording device DA and a data buffer DP. The data processing unit L is constructed in a similar manner. The data processing unit L also contains a memory LR for storing the rules for recording the input signals 1 to be processed with the aid of the data processing unit L. In addition, a preprocessing unit LV, a data recording unit LA and a data buffer LP are provided. Further processing units of the signal processing device 16 are the alarm unit A for monitoring from the input signals 1 a. .4a according to predefinable alarm rules starting from conductive information data. The alarm unit A consists of a memory AR for storing the alarm monitoring rules. The alarms are monitored by evaluating the alarm signals a supplied to the alarm unit, which are forwarded to an alarm monitoring unit AÜ and an alarm archive AA.

The mode of operation of the mobile data acquisition device shown in FIG. 2 will be explained in more detail below on the basis of the respective function blocks. The address assignment unit A2 is formed from address assignment tables which carry out the conversion between source-specific addresses and the input image of the data converter EA. Depending on the source, depending on the type of input signals I1. .I4 the address assignment tables of the address assignment unit A2 are thus also structured differently. However, they all have in common the specification of format (bit, byte, word...), Address in the respective input / output image of the data converter EA, bit offset for bit types and, if necessary, length. The data converter EA is separated into data format areas for space-saving addressing, in which the data received from the various sources is entered as an input image. The tasks of the data converter EA are the equalization between the asynchronous delivery of the data by the sources and the evaluation by the downstream signal processing device 1 . Another object is that the data converter EA provides the data with a uniform interface regardless of the source with a uniform data format. The central element of long-term data acquisition and data monitoring is the data analysis unit D, which is also referred to below as a data analyzer. The data analysis unit D works similarly to an oscilloscope, ie individual selected signals are recorded at defined times. The recording can be started or stopped using the DR recording rules. In contrast to the data processing unit L, the data analysis unit D is used for short-term observation of current events. The corresponding rules DR = for this short-term observation are therefore chosen so that the recording of the data signals with the aid of the recording unit DA takes place only in an operating state "generator of the supply voltage source of the vehicle in operation" or "ignition ON". This ensures that the battery voltage of the vehicle in which the data acquisition device MC is arranged will not be unnecessarily loaded. With the help of the data connection D1 it is shown that the rules of the data analysis unit D are transferred from a central station to the data acquisition device MC at runtime. An example mask for setting the recording rules of the data analysis unit D is shown in FIG. 5, for example.

The functionality of the data processing unit L corresponds essentially the functionality of the data analysis unit D. In contrast to the data analysis unit D, the data processing is used processing unit L for recording data over a län period according to the given rules LR. Such Rules can be, for example: averaging, maxi Malwertbildung, minimum value formation. The rules LR can from a control center in a corresponding parameter / Configuration area. Even in the case of Data processing unit L has two control areas hen, namely one for the normal and one for the so-called called Power Safe operating state. The power safe Operating state identifies the operating state "generator the supply voltage source is not in operation ", which in generally corresponds to the operating state motor OFF. The Da ten preprocessing unit LV is used for preprocessing (on summation, min./max. formation) of the corresponding up Events sampled in the grid.

The alarm notification system A essentially consists of two parts: the alarm archive AA and the alarm monitoring AÜ. The alarm signaling system A monitors signals from the input image of the data converter EA and generates alarm messages. The alarm monitoring AÜ checks the input image according to the alarm monitoring rules AR for events that require notification. If an alarm situation is detected, a corresponding alarm message is entered in the alarm archive AA. The alarm monitoring rules AR determine when an alarm must be marked as coming or going. An alarm message can be passed on, for example, via the GSM driver and a radio transmission unit coupled to it as a so-called SMS message (SMS = Short Message Service) to the head office or to a predetermined recipient (see FIG. 1). Acknowledgment of the alarms that have occurred is also monitored via the alarm signaling system.

Another element of the signal processing device 16 is the so-called data monitoring unit M, which enables online monitoring of values from a control center.

The output interface SA is a so-called data request Interface trained and forms a neutral cut introduce between the functionalities of the data acquisition direction MC and the communication driver for the so-called Operating station, for example for the corresponding Bedi Central observation and observation system. Of communication streiber KT manages the downstream communication media um, for example a WinCC operator control and monitoring system and sets the respective operating and monitoring system specific addressing on the output interface SA around.

Fig. 4 shows an overview of exemplary data configuring a data acquisition device. The configuration database DB contains the configuration data required for the entire system. From this database the databases DB1, DB2 ,. . generated. The first database DB1 contains the configuration data required for the data acquisition unit. The databases Q1. .Qn of the data sources set the behavior of the data sources. The alarm system A defines the rules for alarm monitoring. The databases LR1, LR2 define the recording rules for the data processing unit L (cf. FIG. 3). Furthermore, in the case of the database (not shown in FIG. 4), a classification unit K can be provided, which defines classification rules of a classification unit K. The task of the classification unit K is to evaluate a signal over a longer period of time. The state of the signal is assigned to configurable classes. So z. B. a signal can be divided into 10 classes.

Has the signal z. B. a value range of 0. .999 and 10 equally large classes are configured, each class contains a value range of 100. The first class represents the range of 0.. .99, the second of 100.. .199 etc. The result is then: signal for 140 s in class 1 , for 20 s in class 2 etc. The second database DB2, which is managed in the head office, concerns the alarm archive AA and a symbol management of the related with the data analysis unit D, the data processing unit L, the classification unit K and the data monitoring unit M serves symbol management.

The configuration database DB can be easily added to for example in the form of Excel spreadsheets or with a graph configuration tool. At least definitely Parts of the configuration database DB can contain data ten that can be reloaded from the control center and so can be adapted to new monitoring models etc.

Fig. 5 shows an exemplary input screen for the creation of rules of a data analysis unit. The input mask M contains a first input field EF1 for specifying the input signals to be recorded in each case and a second input field EF2 for specifying the respective recording rules. In the first input field EF1, the signals to be recorded are:
Oil pressure, speed, water temperature and also the time grid for recording the signals. The second input field EF2 is used to specify the respective recording rules, for example a recording is required for the speed if the value is greater than 50.

In summary, the invention thus relates to a device MC and a method for in particular mobile data acquisition with at least one input interface S1. .S4 for supplying input data I1. .I4, in particular data of a vehicle F1. .Fn, a machine etc., with a with the input interface S1. .S4 connectable signal processing device 16 for signal processing of the input interface S1. .S4 supplied data and with an output interface SA for supplying output data 17 of the signal processing device 16 to a transmission device 5 for transmitting the output data 17 to a central 15th An automated and systematic data acquisition for process data acquisition, alarm notification etc. can be achieved in a simple manner in that the signal processing device 16 means A, L, D for recording and evaluating specifiable input data 11th .14 at predeterminable times.

Reference list

1

Signal processing device

5

Transceiver unit

6

GSM antenna

9

Radio interface
10a. . 10n base station

11

Antenna base station

12th

Data connection - base station - network operator

13

Network operator

14

Data connection - network operator - head office

15

Headquarters

16

Radio interface

17th

another base station

18th

Input data - communication driver
A alarm system
AA alarm archive
AS system alarms
AR alarm monitoring rules
AT alarm monitoring unit
L data processing unit
LR memory
LV preprocessing unit
LA data recording unit
LP data buffer
D data analysis unit
DR data analyzer rule interpreter
DA recording device
DP data buffer
E cellular device
F1. . Fn vehicles
MC data acquisition device
OV property management
EA data converter
EA1 bit range
EA2 byte area
EA3 word area
A2 address allocation unit
KT communication driver
Q1. . Q4 data sources
S1. . S4 input interfaces
SA output interface
DB configuration database
DB1 first database
DB2 second database
N cellular network
SV symbol management
M input mask
EF1 first input field
EF2 second input field

Claims (15)

1. Device (MC) for in particular mobile data acquisition with at least one input interface (S1. .S4) for supplying input signals (I1. .I4), in particular operating data of a vehicle (F1. .Fn), a machine etc., with a signal processing device ( 1 ) which can be coupled to the input interface (S1. .Sn) for signal processing of the input signals (I1. .S4) supplied via the input interface (s) (S1. .S4) and for recording specifiable data of the input signals (I1 .I4) at predeterminable times and with an output interface (SA) for supplying output data ( 17 ) derived from the input signals (I1. .I4) in the signal processing device ( 1 ) according to predefinable rules (LR, AR, DR) Signal processing device ( 1 ) to a transceiver ( 5 ) for automatic and / or initiated transmission of the output data ( 18 ) to a control center ( 15 ) and / or to a predetermined receipts r (E). 2. Device according to claim 1, characterized in that the device (MC) has at least one writable memory (AR, DR, LR) for storing an operating system of the device (MC) and / or the predefinable rules (LR, AR, DR) These can be loaded remotely via the transceiver unit ( 5 ). 3. Device according to one of claims 1 or 2, characterized in that the device (MC) has a between the input interface (S1, S2, S3, S4) and signal processing device ( 1 ) arranged data converter (EA) for equalization of the supplied Input signals (I1. .I4) and to provide a uniform data format of the input signals (I1. .S4) supplied via the input interface (s) (S1. .S4). 4. Device according to one of claims 1 to 3, characterized, that the device (MC) between data converter (EA) and Input interface (s) (S1. .S4) provided address Assignment unit (A2), which is used to implement the source-specific addresses of the input signals (I1 ... I4) the address format of the data converter (EA) is provided. 5. Device according to one of claims 1 to 4, characterized in that the signal processing device ( 16 ) comprises a data analysis unit (D) which is provided for recording selected input signals (I1 ... I4) at predetermined times, the default of recording rules from the center ( 15 ) for short-term observation of information derived from the input signals. 6. Device according to one of claims 1 to 5, characterized in that the device (MC) in a motor ( 3 ) operated mobile vehicle (F1. .Fn) is installed and a connecting device for connection to the supply voltage of the vehicle (F1. .Fn) that the device (MC) has means for detecting at least a first operating state "generator of the supply voltage source (B) in operation" and a second operating state "generator of the supply voltage source not in operation", in the second operation state, the work of the data analysis unit (D) is interrupted. 7. Device according to one of claims 1 to 6, characterized in that the signal processing device ( 16 ) has a data processing unit (L) for recording information signals derived from the input signals according to predefinable rules that the device (MC) has a first memory (LR) for storing the rules of the data processing unit (L). 8. Device according to one of claims 1 to 7, characterized, that the first memory (LR) has two memory areas, a first memory area being the rules for operation state "generator of the supply voltage source in operation" and a second memory area the rules for the operation state "generator of the supply voltage source not in Operation "contains. 9. Device according to one of claims 1 to 8, characterized in that the signal processing device ( 16 ) has an alarm unit (A) for monitoring information data derivable from the input signals (I1 ... I4) according to predefinable alarm rules, that the device (MC) has a second memory (AR) for storing the rules of the alarm unit (A). 10. The device according to one of claims 1 to 9, characterized, that the device (MC) an alarm archive (AA) for the entry of alarms have occurred. 11. Device according to one of claims 1 to 10, characterized in that the signal processing device ( 1 ) has an observation unit (DM) for direct observation of input signals (1a. .4a) and / or from the input signals (I1. .I4) from conductive information data. 12. The device according to one of claims 1 to 11, characterized, that the control center has an operating and monitoring system, that also for the direct operation of an operating status  with the device coupled vehicle (F1. .Fn) via Steuer ersignale (I1 ... I4) is provided. 13. The device according to one of claims 1 to 12, characterized, that the device (MC) can be coupled to a GPS receiver is. 14. The device according to one of claims 1 to 13, characterized, that the device (MC) in a car radio receiver and / or in a car radio receiver / mobile phone combination in is tegrated. 15. Method for in particular mobile data acquisition of input signals (I1. .I4) fed via at least one input interface (S1. .Sn), in particular operating data of a vehicle (F1. .Fn), a machine etc., in which the input interface ( S1. .Sn) is coupled to a signal processing device ( 1 ) for signal processing of the input signals (S1. .S4) supplied via the input interface (S1. .S4), in which specifiable data of the input signals (S1. .S4) Time points recorded by the signal processing device ( 1 ) and output data ( 18 ) derived from the input signals (S1... S4) in the signal processing device ( 1 ) according to predefinable rules, which automatically and / or on a transceiver unit ( 5 ) Request to a center ( 15 ) and / or to a predetermined addressee (E) are forwarded.