Pressure-sensitive capacitive measurement device and method for touch-sensitive and contactless interfaces

Abstract

A capacitive measurement device for control interfaces, includes: (i) a support plate (2) having elements for attachment (4) to a control interface (3), (ii) first electrodes (5) arranged on a first surface of the support plate (2) opposite the control interface (3) and including first active electrodes (5), (iii) electronic capacitive measurement elements capable of enabling the obtainment of proximity and/or contact information of objects of interest (1), and (iv) second electrodes (6, 7) arranged on a second surface of the support plate (2) facing the control interface (3) and including second active electrodes (6) connected to the electronic capacitive measurement elements such as to enable the obtainment of measurements of movement and/or deformation of the support plate (2). A method and apparatus implemented in the device are also described.

Claims

1. A capacitive measurement device, comprising: a support plate made from a dielectric material, with a resilient material coupled to the support plate and configured for fixing the support plate onto a display referenced to a ground potential, first active electrodes made from an electrically conductive material, arranged on a first face of said support plate opposite the display and configured to receive a first potential different from the ground potential, wherein each of a plurality of the first active electrodes formed on a central area of the support plate are configurable for individually detecting an approach or contact of one or more objects of interest, an electronic capacitive measurement amplifier configured for allowing data on the approach or contact of the one or more objects of interest to be obtained by measurements of capacitive coupling with said first active electrodes, and second active electrodes made from an electrically conductive material, arranged on a second face of said support plate toward the display and configured to receive a second potential, the second active electrodes selectively connectable to said electronic capacitive measurement amplifier so as to allow measurements of one or both of a displacement and deformation of said support plate to be obtained by measurement of capacitive coupling between said second active electrodes and said display, wherein the electronic capacitive measurement amplifier is configurable for receiving a guard potential at a first input, wherein the electronic capacitive measurement amplifier is selectively couplable to the first active electrodes at a second input for generating the first potential, or to the second active electrodes at the second input for generating the second potential, and wherein the first and second potentials are referenced to the guard potential through the electronic capacitive measurement amplifier.

2. The device of claim 1, further comprising one or more guard electrodes configured for receiving the guard potential, the guard potential held at the first potential and different from the ground potential, said one or more guard electrodes being arranged so as to electrically shield, respectively, on their face oriented toward the support plate, the first active electrodes.

3. The device according to claim 2, further comprising plurality of switches configured for connecting either the first active electrodes or the second active electrodes, to the electronic capacitive measurement amplifier or to the guard potential.

4. The device of claim 2, wherein the electronic capacitive measurement amplifier is at least partially referenced to the guard potential.

5. The device of claim 4, in which the first potential is equal to the guard potential.

6. The device of claim 1, wherein the electronic capacitive measurement amplifier is configured for obtaining data on the approach or the contact of the one or more objects of interest by capacitance measurements between each of the plurality of the first active electrodes and the one or more objects of interest.

7. The device of claim 1, the first active electrodes including excitation electrodes and measurement electrodes, the measurement electrodes configurable for being capacitively coupled to said excitation electrodes, and wherein the electronic capacitive measurement amplifier is configurable for obtaining data on the approach or the contact of the one or more objects of interest by measurements of the variation of coupling capacitance between said excitation and measurement electrodes.

8. The device of claim 1, wherein the electronic capacitive measurement amplifier is configurable for obtaining measurements of one or both of the displacement and deformation of said support plate by measurements of capacitance between said second active electrodes and said display.

9. A human-machine interface device comprising the display and the electronic capacitive measurement amplifier according to claim 1.

10. The human-machine interface device according to claim 9 wherein the display is provided with a display screen, and the electronic capacitive measurement amplifier is coupled to the support plate and the first active electrodes which are transparent.

11. A device of one of the following types: smartphone, tablet, display screen, computer, control pad for a machine or vehicle, comprising the human-machine interface device according to claim 9.

12. A capacitive measurement method, utilizing (i) a support plate made from a dielectric material with a resilient material coupled to the support plate and configured for fixing onto a display referenced to ground potential, (ii) first active electrodes made from a material that is electrically conductive, arranged on a first face of said support plate opposite the display, said first active electrodes configured to receive a first potential different from the ground potential, wherein each of a plurality of the first active electrodes formed on a central area of the support plate are configurable for individually detecting an approach or contact of one or more objects of interest, and (iii) an electronic capacitive measurement amplifier, the method comprising: obtaining data on the approach or contact of the one or more objects of interest by measurement of capacitive coupling with said first active electrodes, obtaining measurements of one or both of a displacement and deformation of said support plate by measurements of capacitive coupling between second active electrodes and said display, said second active electrodes (i) made from a material that is electrically conductive, arranged on a second face of said support plate toward the display and (ii) receiving a second potential and being selectively connectable to said electronic capacitive measurement amplifier, receiving a guard potential at a first input of the electronic capacitive measurement amplifier, selectively coupling a second input of the electronic capacitive measurement amplifier to the first active electrodes for generating the first potential, or to the second active electrodes for generating the second potential, and referencing the first and second potentials to the guard potential through the electronic capacitive measurement amplifier.

13. The method of claim 12, further comprising: connecting the first active electrodes to the electronic capacitive measurement amplifier, and connecting the second active electrodes to the guard potential by plurality of switches, obtaining data on the approach or the contact of the one or more objects of interest.

14. The method of claim 12, further comprising: connecting the second active electrodes to the electronic capacitive measurement amplifier, and connecting the first active electrodes to the guard potential by a plurality of switches, obtaining data on one or both of the displacement and deformation of the support plate.

15. The method of claim 12, further comprising: obtaining data on the approach or the contact of the one or more objects of interest, and when at least one object of interest is at a distance less than a predetermined distance, or in contact with at least one of the first active electrodes, obtaining data on one or both of the displacement and deformation of the support plate.

16. The method of claim 12, further comprising determining one or both of a pushing force and a pressure from data on one or both of the displacement and deformation of the support plate.

17. A device of one of the following types: smartphone, tablet, display screen, computer, control pad for a machine or vehicle, configured for performing the method according to claim 12.

Description

DESCRIPTION OF THE FIGURES AND EMBODIMENTS

(1) Other advantages and features of the invention will become apparent on reading the detailed description of implementations and embodiments which are in no way limitative, and from the following attached drawings:

(2) FIG. 1 shows a diagrammatic view in cross section of a device according to the invention;

(3) FIG. 2 shows an embodiment of the detection electronics.

(4) A description will be given of an example embodiment of a device according to the invention making it possible to manufacture touch-sensitive and contactless interfaces for systems or devices such as mobile telephones (smartphones), tablets, computers or control pads.

(5) With reference to FIG. 1, the capacitive measurement device according to the invention comprises a support plate 2 made from a substantially transparent dielectric material such as glass or a polymer such as PET.

(6) This support plate 2 is fixed onto a command interface 3 by fixing means 4 suitable for deforming under the effect of pressure. These fixing means 4 can comprise for example springs or resilient materials.

(7) The command interface 3 comprises a display screen, for example of the TFT (thin-film transistor) or OLED (organic light-emitting diode) type.

(8) The command interface 3 and the superimposed capacitive measurement device constitute a human-machine interface for the system.

(9) The support plate 2 comprises first electrodes 5 distributed over its face opposite to the command interface 3. These first electrodes 5 make it possible to detect the approach and/or contact of one or more object(s) of interest 1 such as a finger 1 by measurement of the capacitive coupling that is established between them and the finger 1.

(10) The distance between the finger 1 and the electrodes 5 can be deduced from the capacitive coupling measurement, while the location of the finger 1 in the plane of the support plate 2 is obtained from the position of the first electrodes 5 which detect the presence of the finger 1.

(11) The support plate 2 also comprises second electrodes 6, 7 on its face toward the command interface.

(12) Some of these second electrodes, or second active electrodes 6, can be used for measuring distances between the support plate 2 and the command interface 3. These electrodes 6 are located on the edges and optionally toward the middle of the support plate 2.

(13) The second electrodes also comprise second guard electrodes 7, excited at an alternating electrical guard potential.

(14) The first electrodes 5 and the second electrodes 6, 7 are made from a substantially transparent material such as ITO (tin-doped indium oxide) deposited on the support plate 2. Some electrodes placed on the periphery of the support plate 2 and outside the transparent surface can be made from a non-transparent material.

(15) The support plate 2 can be deformed and/or displaced toward the command interface 3 under the effect of a pressure exerted by the finger 1.

(16) With reference to FIG. 2, the first electrodes 5 and the second active electrodes 6 are connected to electronic capacitive measurement means 17.

(17) These electronic capacitive measurement means 17, in the embodiment in FIG. 2, are provided in the form of a floating capacitive measuring bridge system as described for example in document FR 2 756 048 by Rozire.

(18) The detection circuit comprises a part known as a floating part 16 the reference potential 11 of which, called guard potential 11, oscillates with respect to the ground 13 of the overall system, or to the earth. An excitation source, or an oscillator 14 generates the alternating potential difference between the guard potential 11 and the ground 13.

(19) The floating part 16 comprises the sensitive part of the capacitive detection system, represented in FIG. 2 by a charge amplifier. It can of course also comprise other means of processing and conditioning the signal, including digital means or microprocessor-based means, also referenced to the guard potential 11. These means of processing and conditioning make it possible, for example, to calculate data relating to distance and pressure from capacitive measurements.

(20) The power supply of the floating part 16 is ensured by floating power transfer means 15, comprising for example DC/DC converters.

(21) This capacitive measurement system makes it possible to measure an item of capacitance data between at least one measurement electrode, which can be a first electrode 5 or a second active electrode 6, and an object such as, respectively, the finger 1 or the command interface 3.

(22) The object to be detected 1 must be connected to a potential different from the guard potential 11, such as for example the ground potential 13. This configuration is met for the finger 1 of a user, whose body defines a 20 ground, and for the command interface 3, which is an electronic system referenced overall to the ground 13.

(23) An array of switches or analogue switches 10, controlled by electronic control means, makes it possible to select a measurement electrode 5, 6 and connect it to the capacitive detection electronics 17 in order to measure the coupling capacitance thereof with the object 1 or the command interface 3, respectively. The switches 10 are configured in such a way that an electrode 5, 6 is connected either to the capacitive detection electronics 17, or to the guard potential 11.

(24) A guard shield 12 connected to the guard potential 11 protects the sensitive part of the detection system. Similarly, the electrodes 5, 6 which are not active are connected to the guard potential 11 by the switches 10. The device also comprises guard electrodes, including the second guard electrodes 7, which remain connected to the guard potential 11.

(25) Thus, an active electrode 5, 6 connected by a switch 10 to the capacitive detection electronics 17 is surrounded, in particular on its rear face, by guard planes constituted at least partially by first and/or second electrodes 5, 6, 7 connected to the guard potential 11.

(26) As the active measurement electrode 5, 6 is also at the guard potential 11, it is therefore possible to avoid stray capacitances between this electrode and its surroundings in such a way that only the coupling with the object of interest 1 is measured with a maximum sensitivity.

(27) The floating electronics 16 are connected at the output to the system electronics 18 referenced to ground by electrical connections that are compatible with the difference in reference potentials. These connections can comprise for example differential amplifiers or optocouplers.

(28) A measurement method implemented in the device according to the invention will now be described.

(29) Firstly, the second electrodes 6, 7 are all connected to the guard potential. The scanners 10 sequentially poll the first active electrodes 5 in order to detect the approach of command objects 1.

(30) When a command object is identified close to or in contact with first electrodes 5, the scanners 10 are controlled so as to also poll second active electrodes 6. The measurements obtained from these second active electrodes 6 make it possible to obtain data on displacement and/or deformation of the support plate 2, from which it is possible to deduce data on pressure exerted by the command object 1 on the support plate 2.

(31) When second active electrodes 6 are connected to the electronics 17, the first electrodes 5, or at least those placed opposite the second active electrodes 6, are connected to the guard potential 11.

(32) As a result of this arrangement of the guard planes, it is ensured that the first active electrodes 5 are only sensitive to objects found on their side of the support plate 2, while the second active electrodes 6 are only sensitive to the presence of the command interface 3.

(33) Data on the position of the object or the objects 1 in space relative to the support plate 3 and data on pushing or pressure exerted on this support plate 3 are obtained in this way.

(34) These data are processed by the detection electronics 17 and transmitted to the system electronics 18 to be utilized in particular in the human-machine interface.

(35) The pressure or pushing data reliably obtained by the device and the method according to the invention make it possible to obtain a validation of commands that is more certain and more comfortable for the user. It also makes it possible to add a dimension or a degree of freedom to the human-machine interface, by allowing a distinction between a light brush and a push, or even commands proportional to the pressure exerted.

(36) According to variants:

(37) The support plate 2 can be sufficiently flexible to deform under the effect of an exerted pressure, and to be fixed by flexible or rigid fixing means 4;

(38) The first electrodes 5 and the second electrodes 6, 7 can be arranged on the same side of the support plate 2, in successive layers separated by isolating layers;

(39) the first and second electrodes 5, 6, 7 can all be connected to the measurement electronics 17 by means of switches 10;

(40) Several measurement electronics 17 can be utilized, each capable of being connected to a set of electrodes 5, 6, so as to be able to carry out a plurality of measurements in parallel;

(41) Intelligent scanning strategies can be implemented, for detecting and monitoring objects 1 with a minimum of scanning operations. Conversely, the first and second active electrodes 5, 6 can all be scanned systematically, even in the absence of objects;

(42) The second active electrodes 6 can be few in number, for example toward the edges, and detect only overall movements of the support plate 2. They can also be sufficient in number, distributed over the surface, to carry out mapping of the deformation of the support plate 2;

(43) The first electrodes 5 can comprise electrodes in the form of intersecting rows and columns, for direct measurements of capacitance with the object 1, or measurements of coupling capacitance interference due to the presence of the object 1;

(44) The measurements of displacement and/or deformation of the support plate 2 can comprise absolute measurementsin relation to a reference position and/or shape of the support plate 2and/or relative measurementsi.e. measurements of variation of position and/or shape. They can also comprise measurements of speed of displacement and/or deformation of the support plate 2, as well as all types of measurements relative to a displacement and/or a deformation. They can in particular comprise measurements making it possible to characterize a pressure exerted statically and/or dynamically.

(45) It is noteworthy that an advantage of the invention is to be able to use the entire command interface 3 as a target. This advantage is made possible due to the fact that the detection electronics are referenced to a defined-frequency alternating guard potential 11. It is thus possible to obviate the effect of the electrical signals referenced to the ground 13 which are present in the command interface 3.

(46) According to another advantageous aspect, the support plate 2 supports all the electrodes 5, 6, 7 and the invention does not need any particular adaptation of its environment in order to operate. It can thus very easily be incorporated into a control interface 3 without the need for any particular adaptation of the display device for example.

(47) Of course, the invention is not limited to the examples that have just been described and numerous adjustments can be made to these examples without exceeding the scope of the invention.