Sensor for detecting environmental parameters and method of calibrating the sensor

Abstract

The invention relates to a sensor (1) for detecting environmental parameters, comprising a transmission device (3) by means of which an output signal of the sensor (1) can be emitted, and a correction device (4) by means of which the sensor measurement value can be corrected for the emission of a correct output signal, which sensor is to be easy to produce, and wherein only a small output is to be required for a method for calibrating a sensor of this type. According to the invention, the sensor is calibrated by means of the correction device thereof, on the basis of cloud-based data.

Claims

1. A sensor for detecting environmental parameters and generating an output signal corresponding thereto and having a quality-of-service indicator of signal quality, the sensor comprising: a transmitter that can emit the output signal of the sensor, and an adjustment device for adjusting a sensor measurement by emitting a correct output signal for initial calibration of the sensor by the adjustment device on the basis of cloud-based data by initially setting the quality-of-service indicator to a characteristic value and, after a predetermined operating time without calibration, lowering the quality-of-service indicator below the characteristic value, and after calibration resetting the quality-of-service indicator to a value above the characteristic value.

2. The sensor according to claim 1, further comprising in combination with the sensor: a server for accessing the cloud-based data for determining adjustment data for the sensor from the cloud-based data and for passing the determined adjustment data to the sensor or to the adjustment device thereof.

3. The sensor according to claim 2, wherein the sensor measurement of the sensor is adjustable on the server based on the determined adjustment data and the server makes the adjusted output signal available to the sensor.

4. The sensor according to claim 3, wherein the adjustment data can be determined and stored from the sensor measurement and the adjusted output signal made available to the sensor.

5. The sensor according to claim 1, wherein the cloud-based data is accessed and the adjustment data is determined on the basis of the accessed cloud-based data.

6. A method of calibrating a sensor for detecting environmental parameters, the method comprising the steps of: initially calibrating the sensor for emitting correct output signals on the basis of cloud-based data having a quality-of-service indicator set to the characteristic value, and, after a predetermined operating time without calibration, lowering the quality-of-service indicator below the characteristic value, and after calibration resetting the quality-of-service indicator above the characteristic value.

7. The method according to claim 6, further comprising the step of: storing the cloud-based data as data records according to sensor identification, time and place of a plurality of identical sensors.

8. The method according to claim 6, further comprising the step of: subjecting the correct output signals of the sensor to a plausibility check based on the cloud-based data.

9. The method according to claim 6, wherein the step of initially calibrating the sensor also includes the substep of: determining adjustment data for the correct output signals of the sensor and subsequently calibrating the sensor on the basis of the determined adjustment data.

10. The method according to claim 9, further comprising the step of: storing the adjustment data in the sensor.

11. The method according to claim 6, further comprising the steps prior to initially calibrating the sensor of: receiving sensor data from a cloud-based service, determining adjustment data for the sensor from the sensor data received from the cloud-based service, and using the determined adjustment data for the further processing in the cloud of sensor data of the sensor.

Description

BRIEF DESCRIPTION OF THE DRAWING

(1) The invention is explained in greater detail below with the help of embodiments with reference to the drawing whose sole FIGURE depicts an embodiment of a method according to the invention for calibration of sensors for detecting environmental parameters.

SPECIFIC DESCRIPTION OF THE INVENTION

(2) A sensor 1 according to the invention described below with the help of the single FIGURE, which sensor can be calibrated using a method according to the invention for the calibration of sensors 1 for detecting environmental parameters, has a sensor element 2 with which the environmental parameter to be detected can be measured.

(3) The environmental parameter to be detected or monitored may be, for example, ozone, NO.sub.x, CO, CO.sub.2 concentrations, air temperature, humidity, solar radiation, UV (ultraviolet) radiation, dust load, position, speed, etc. The list of environmental parameters referred to above is only given by way of example. A plurality of other environmental parameters can be detected or monitored using sensors 1 fitted with correspondingly designed sensor elements 2.

(4) Sensors 1 of this kind may be permanently installed in buildings or measuring stations, for example. They may also be provided as mobile sensors, for example in vehicles or mobile phones. The embodiment as “wearables”, for example in items of clothing, is also possible.

(5) Most sensors 1 of this kind used to detect environmental parameters detect the respective environmental parameters or data, in order to supply the owners or a community with these measurements.

(6) Access to processed and, for example, visualized measurements from a large number of sensors 1 of this kind for detecting environmental parameters is then provided to a community by means of a cloud-based device, for example.

(7) With a procedure or a method of this kind, based on the present temperature data and the likewise present positional data of the sensors 1 detecting these temperature data over a geographical range, for example a town or a region of numerous distributed—including mobile—sensors 1, a temperature map for the town or region concerned can be created and made accessible.

(8) Similarly, a map depicting the air quality of a town or region can be made available so that a user is able to avoid areas with currently high concentrations of harmful substances, for example.

(9) Sensor 1 includes a transmitting device 3 and an adjustment device 4. By means of the transmitting device 3, an output signal of the sensor 1 can be emitted. By means of the adjustment device 4 the sensor 1 can be calibrated to emit an adjusted output signal.

(10) Sensor calibration by means of the adjustment device 4 is achieved in that one or more adjustment values or adjustment functions for the sensor measurement or the output signal of the sensor 1 are calculated for the sensor 1. These adjustment values or adjustment functions are referred to below as “adjustment data”.

(11) These adjustment data are calculated in the embodiment of the invention shown in the FIGURE on a server 5 by a “community-based (CB) service”. With a CB service the measurement data from a large number of sensors 1 of this kind—including mobile sensors—is gathered and stored as data records along with the respective identification of the sensor 1, the time and the place of the measurement.

(12) With an adequately large number of sensors 1 of this kind and corresponding sensor data records associated therewith, the aforementioned CB service can calculate or estimate on the basis thereof the extent to which the measurement data of a sensor 1 correlate with those of other corresponding sensors 1 in time and place.

(13) Accordingly, the adjustment data can then be re-determined for the respective sensor 1 by means of current calculations.

(14) The adjustment data thereby determined or calculated are taken into account by the CB service when processing the measurement data of the respective sensor 1 before the output signals of the sensor 1 are visualized and published.

(15) Insofar as there is a bidirectional connection to the sensor 1, these adjustment data are also supplied to the sensor 1. They can be supplied to the sensor 1 by the server 5 or the CB service. The exchange of adjustment data can take place directly over the air or also through a wired connection.

(16) The adjustment data can be stored in sensor 1. An adjustment of the output signals of the sensor 1 is then possible in offline mode too. The adjustment data are then applied to the measurement data thereof in sensor 1. The correspondingly adjusted measurement data are then supplied to the users or the community in the cloud 6.

(17) Alternatively, the sensor 1 may supply its non-adjusted measurement data and the adjustment data.

(18) It is also possible for the sensor 1 to supply its unadjusted measurement data and the CB service the adjustment data of the respective sensor 1 to the community.

(19) With its adjusted or unadjusted measurement data, the sensor 1 can supply a QoS (Quality of Service) indicator assigned to it, which is a characteristic value for the signal quality. This QoS indicator may be supplied by the sensor 1 and/or managed in a database. This QoS indicator may be assigned to an individual sensor 1 or a group of sensors 1.

(20) If the sensor 1 is a low-cost sensor, this sensor 1 may initially be assigned a mean QoS indicator, for example, such as a 5 in a range of values from 0 to 10. After a long service life or operating time without calibration, the QoS indicator can be lowered to a value below 5. Following calibration, the QoS indicator can be increased again to a higher value.

(21) If the sensor 1 is a high-value sensor, for example a calibrated sensor, this sensor 1 may initially be assigned a high QoS indicator, for example of 10 in the aforementioned range of values from 0 to 10. After a long service life or operating time without calibration, this QoS indicator can then be lowered to a value below 10. Following calibration, the QoS indicator can once again be increased to a higher value.

(22) The QoS indicators assigned to the respective sensors 1 are then decisive in relation to the extent to which the measurements or output signals of the respective sensors 1 are included in the total calculation of the environmental parameter value concerned.