SENSOR SYSTEM AND METHOD FOR OPERATING A SENSOR SYSTEM

Abstract

A sensor system including one sensor element for acquiring at least one measured variable, a circuit system for operating the sensor device and for generating sensor data based on the sensor signals, and a configuration data memory for configuration data. The sensor system is able to be alternatively operated in at least in an active mode, and in a sleep mode. The circuit system is configured in such a way that the memory content of the configuration data memory is independent of the respective operating mode of the sensor system, so that the stored configuration data are maintained in a sleep mode, and the sensor system is configured in such a way that the at least one part that is switched to a currentless state in the sleep mode is reconfigured on the basis of the stored configuration data when a change to an active mode is initiated.

Claims

1-13. (canceled)

14. A sensor system, comprising: at least one sensor element configured to sense at least one measured variable in the form of electrical sensor signals; a circuit system configured to operate the sensor device and to generate sensor data based on the sensor signals; and at least one configuration data memory storing configuration data; wherein the sensor system is alternatively operable in different operating modes, the different operating modes including at least: (i) an active mode in which sensor data are generated, and (ii) a sleep mode in which no sensor data are generated and at least one part of the sensor system is switched to a currentless state, and wherein: the circuit system is configured in such a way that memory content of the at least one configuration data memory is independent of the operating modes of the sensor system, so that the stored configuration data are maintained in a sleep mode, and the sensor system is configured in such a way that the at least one part that is switched to a currentless state in the sleep mode is reconfigured based on the stored configuration data when a change to the active mode is initiated.

15. The sensor system as recited in claim 14, further comprising: at least one interface for the communication with an external processing device, wherein user-specific and/or application-specific configuration data are optionally able to be written to the at least one configuration data memory via the external interface independently of the operating modes.

16. The sensor system as recited in claim 14, wherein the circuit system is configured in such a way that the active mode is started when a change from the sleep mode to the active mode is initiated.

17. The sensor system as recited in claim 14, wherein the sensor system is operated in at least two active modes, which include a continuous operating mode and/or an operating-cycle mode.

18. The sensor system as recited in claim 14, wherein the sensor system is able to be operated in at least two sleep modes, which differ from each other by respective parts of the circuit system that are able to be switched to a currentless state, wherein in at least one of the sleep modes, an analog part of the circuit system is switched to a currentless state, and/or in at least one of the sleep modes, a digital part of the circuit system is switched to a currentless state, and/or in at least one of the sleep modes, a data memory for sensor data is switched to a currentless state.

19. The sensor system as recited in claim 15, wherein the interface is connected to the circuit system, and using the interface, a change in the operating mode is able to be initiated by an external processing unit.

20. The sensor system as recited in claim 19, wherein the circuit system is configured in such a way that information about the operating mode in which the sensor system is operated is able to be transmitted to the external processing device via the interface.

21. The sensor system as recited in claim 15, wherein the interface is a 12C interface or a SPI interface or a 13C interface.

22. The sensor system as recited in claim 14, wherein the sensor element is a micromechanical sensor element, the micromechanical sensor element being configured to sensor: (i) a pressure, and/or (ii) an acceleration, and/or (iii) rate of rotation, and/or (iv) orientation in space, and/or (v) temperature, and/or (vi) humidity, and/or (vii) gas composition and/or (viii) particle concentration.

23. The sensor system as recited in claim 14, wherein the circuit system is configured to provide multiple sleep modes and/or multiple active modes for operating the sensor system, which differ from one another by energy consumption.

24. The sensor system as recited in claim 14, wherein the sensor system draws less than two microamperes in at least one sleep mode, in a temperature range of at least 0 C.-65 C.

25. A method for operating a sensor system, the sensor system including at least one sensor element configured to sense at least one measured variable in the form of electrical sensor signals, a circuit system configured to operate the sensor device and to generate sensor data based on the sensor signals, and at least one configuration data memory storing configuration data, wherein the sensor system is alternatively operable in different operating modes, the different operating modes including at least: (i) an active mode in which sensor data are generated, and (ii) a sleep mode in which no sensor data are generated and at least one part of the sensor system is switched to a currentless state, and wherein: (i) the circuit system is configured in such a way that memory content of the at least one configuration data memory is independent of the operating modes of the sensor system, so that the stored configuration data are maintained in a sleep mode, and (ii) the sensor system is configured in such a way that the at least one part that is switched to a currentless state in the sleep mode is reconfigured based on the stored configuration data when a change to the active mode is initiated, the method comprising: switching at least one part of the sensor system to a currentless state in the sleep mode; and reconfiguring the at least one part using the configuration data stored in the configuration data memory when a change is initiated from the sleep mode to the active mode.

26. The method as recited in claim 25, wherein after the reconfiguration of the at least one part of the sensor system, the sensor system is operated in the active mode.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0031] FIG. 1 shows a conventional sensor system in schematic form.

[0032] FIG. 2 shows steps of a conventional method during a change from a sleep mode to an active mode of a conventional sensor system.

[0033] FIG. 3 shows a sensor system according to a specific embodiment of the present invention, in schematic form.

[0034] FIG. 4 shows steps of a method during a change from a sleep mode to an active mode of a sensor element according to a specific embodiment of the present invention.

[0035] FIG. 5 shows operating modes of a sensor element according to a specific embodiment of the present invention in schematic form.

DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS

[0036] FIG. 1 shows a conventional sensor system in schematic form.

[0037] FIG. 1 shows a sensor system 1 in schematic form. Among others, sensor system 1 includes a digital part 2 and an analog part 3. Analog part 3 is switchable in this case, which means that it is able to be switched on and off, but digital part 2 is not, meaning that it is not able to be switched off but will always be supplied with energy, i.e., independently of the respective operating mode.

[0038] In detail, digital part 2 includes a digital core 22, which is connected to a microcontroller 21, a digital signal processor 23, a sensor data memory 25, in particular in the form of a first-in/first-out FIFO memory, and a non-volatile memory 24.

[0039] Configuration data 100 for the configuration of sensor system 1 are stored in a volatile memory, which is switched off when the sensor system is operated in a sleep mode.

[0040] Analog part 3 has an excitation signal generator 31 and an analog front end 32 including an analog-to-digital converter.

[0041] In addition, sensor system 1 includes a sensor element 4, which is connected to excitation signal generator 31 and analog front end 32. In the same way, sensor system 1 includes a part 5, which has a digital interface 51 that is connected to digital core 22 on the one hand and to a processing unit 7 on the other hand for an external communication. Part 5, too, is unable to be switched off. Sensor system 1 furthermore includes a voltage supply 6 for the supply of energy.

[0042] FIG. 2 shows steps of a conventional method during the change from a sleep mode to an active mode of a conventional sensor system.

[0043] In FIG. 2, when sensor system 1 according to FIG. 1 is in a sleep mode SM and analog part 3 is switched off, a user first sends what is termed a wake-up signal to sensor device 1 with the aid of external processing unit 7 in a first step S1. Sensor system 1 receives the wake-up signal via interface 51 and transmits the signal to digital core 22. Digital core 22 processes the signal and then switches analog part 3 on so that it is supplied with energy. This requires a certain amount of time (reference numeral S2).

[0044] This is followed by a configuration of sensor system 1 by the user with the aid of external processing unit 7 in a third step S3 in that configuration data 100 are transmitted via interface 51. Configuration data 100 are made available to the components of sensor system 1 to be configured, i.e., as shown in FIG. 1, to all components of analog part 3 and microcontroller 21, digital signal processor 23 and digital core 22, for their configuration.

[0045] After the configuration of the components has been concluded, sensor system 1 receives a signal from the user via external processing unit 7 for starting the active mode in a fourth step S4. In a fifth step S5, sensor system 1 is then operated in the active mode, and sensor element 4 carries out measurements. In particular steps S2, i.e., the wake-up of sensor system 1, as well as S3, i.e., the configuration of sensor system 1, consume considerable time. In addition, sensor system 1 has to interact with the user during steps S1-S4, not only through the wake-up signal in step Si but also by the configuration of sensor system 1 in step S3 and the starting of the active mode in step S4. In total, time t1 is required for the interaction.

[0046] FIG. 3 shows a sensor system according to one specific embodiment of the present invention in schematic form.

[0047] In FIG. 3, a sensor system 1 according to FIG. 1 is essentially shown in schematic form. In contrast to sensor system 1 according to FIG. 1, in sensor system 1 according to FIG. 3 digital part 2 is now also switchable, or in other words, is able to be switched on and off. In addition, a configuration data memory 100 in part 5 is provided, which is not switchable, i.e., is always supplied with energy. Moreover, sensor data memory 25 may also be located in part 5 instead of in digital part 2, so that access to stored sensor data via interface 51 is possible also in a sleep mode of sensor system 1. The components of digital and/or analog part 2, 3 may also be developed in such a way that they are able to be switched off and on separately in each case. Also, groups of components may be defined or formed so that when the group is switched on or off, the respective components that are allocated to the group are switched on or off. In the same way, the illustrated components themselves may be provided with a separate energy supply in switched-off areas, e.g., be directly connected to interface 51 or voltage supply 6, so that they are switched off when the part is switched off, but are able to be switched on regardless of whether the part is switched off. In the same way, this may generally prevent such a component from being switched off when the corresponding part is switched off.

[0048] FIG. 4 shows steps of a method during a change from a sleep mode to an active mode of a sensor system according to a specific embodiment of the present invention.

[0049] In FIG. 4, when the sensor system is in a sleep mode SM and analog part 3 as well as digital part 2 are switched off, a user first sends a wake-up signal and a signal for starting the active mode with the aid of external processing unit 7 to sensor system 1 in a first step T1. Sensor system 1 receives the two signals via interface 51 and subsequently switches analog part 3 and digital part 2 on so that they are supplied with energy. This requires a certain amount of time (reference numeral T2).

[0050] While analog and digital parts 3, 2 are switched on, they are configured using configuration data 100 from configuration data memory 100. In third step T3, sensor system 1 is operated in the active mode and carries out measurements with the aid of sensor element 4.

[0051] Since the active mode is automatically started immediately thereafter, time t2 required for the interaction with external processing unit 7 is considerably reduced. In other words, time t2 according to FIG. 4, during which sensor system 1 according to FIG. 3 interacts with a user, is much shorter than time t1 according to FIG. 2. An external configuration of sensor system 1, i.e., by a user, is not required because the configuration data are held in readiness also during the sleep mode.

[0052] FIG. 5 shows operating modes of a sensor element according to a specific embodiment of the present invention in schematic form.

[0053] In FIG. 5, operating modes of a sensor system 1 according to a specific embodiment of the present invention are shown in schematic form. After being supplied with electrical energy, sensor system 1 is started up, which is also known as a power-up PU, and then is initially operated in a sleep mode SM. In addition to sleep mode SM, sensor system 1 may be operated in an additional deep sleep mode DSM as an operating mode and in two different active modes OM1, OM2. Moreover, it is possible to switch between the individual operating modes as desired, so that, for instance, it is possible to switch from deep sleep mode DSM to second active mode OM2 or from sleep mode SM to deep sleep mode DSM and from deep sleep mode DSM to first active mode OM1. The switch between the individual modes is able to be set by a predefined configuration-bit field in a respective register of sensor system 1, for example, or also in configuration data memory 100. Alternatively, corresponding configuration bits may also be stored in non-volatile memory 24. They are then able to be read out or modified via interface 51 with the aid of processing unit 7. To this end, sensor system 1 may be developed to check on a regular basis whether or not the stored value allocated to the respective operating mode has changed. If it has changed, then a corresponding change of the operating mode will be initiated accordingly. For example, if a change from an active mode OM1 to a sleep mode SM is initiated, parts to be switched off that are allocated to sleep mode SM are switched off. When they are finally switched off, this is able to be communicated to external processing unit 7 via interface 51 as a confirmation, as the case may be.

[0054] In summary, at least one specific embodiment of the present invention has at least one of the following advantages: [0055] a reduced power consumption [0056] a simple implementation [0057] reduced time until a dedicated application of the sensor is started [0058] a reduction in the time of the communication of the sensor with a user.

[0059] Although the present invention has been described on the basis of preferred exemplary embodiments, it is not restricted to these exemplary embodiments but may be modified in a variety of ways.