NO153628B - CONTROL SWITCH, AND COMPOSITION OF SUCH SWITCHES. - Google Patents

Description

The invention broadly relates to a touch control switch

a dielectric plate on one side of which a first conductive layer is arranged and on the opposite side of which there are arranged second and third conductive layers which are in a separate, superimposed relationship to the first layer, a respective electrical connection being arranged to the second and the third layer for use in detecting operation of the switch with a read signal, the read signal being applied to one connection and a corresponding, induced signal being extracted from the other connection. Furthermore, the invention relates to an assembly of a number of such touch control switches.

Touch control switches are switches that are actuated in accordance with the change in capacitive coupling between a "touched" plate and an adjacent plate as a result of an operator's finger approaching the "touched" plate. In a switch of the type indicated at the outset, the aforementioned conductive layers are superimposed in such a way that the capacitive coupling is produced between the first layer and the second and third layers. A read signal is applied, e.g. on the second layer, and the corresponding output pulses which are induced in the third layer, are analyzed to determine whether or not the switch has been operated as a result of a finger approaching the first conductive layer, as such approach entails a drop in the output signal's amplitude, which can be used to start a control function.

Electroluminescent devices are also known

in which a phosphor layer is placed between two electrodes so that it is excited by an electrical voltage applied between the electrodes, and emits light which can pass through one of the electrodes to produce a visible image. Electroluminescent devices have been used together with electric switches to signal control functions, but the devices and switches have been independent of each other.

According to the invention, a touch control switch of the type indicated at the outset is provided, which is characterized by the fact that it further comprises a phosphor layer in contact with the second conductive layer, an electrode which is superimposed on the phosphor layer, and an input connection to the electrode for applying a lighting control signal, the dielectric plate and the first and second conductive layers consisting of light-transmitting material so that light passes through it from the phosphor layer when this is excited by a potential difference produced by signals on the second conductive layer and the electrode.

The invention thus produces a touch control switch combined with an electroluminescent device to give visible signals depending on the switch's maneuvering, an operating element in the form of the aforementioned second conductive layer being used for both the switch and lighting functions.

The reading signal can be used to ensure that the breaker

and the lighting functions act simultaneously. Alternatively, a separate signal can be used for the lighting function. In the two cases, either the read signal or the separate signal will ensure that the phosphor is excited during the control of the illumination signal.

The assembly provided according to the invention

of a number of touch control switches of the specified design is characterized by the fact that the switches are arranged in a matrix arrangement with n groups of m switches with m read inputs each connected to a respective set of switches comprising one from each group, with n read outputs each connected to all switches in a respective group, and with n lighting control inputs which are each connected to the electrodes of all switches in a respective group, a processor being connected to the aforementioned logic and lighting control inputs, in order to apply signals to these to illuminate selected switches, and the processor is further connected to said read outputs and comprises a device for supplying a read signal to each of the read inputs in sequence and a device for analyzing the signals on the read outputs at each supply of the read signal to determine whether any of the respective switch sets has been operated on.

The invention shall be described in more detail below

by way of example and with reference to the drawings, in which fig. 1 shows an expanded, schematic representation of eh touch control switch according to the invention, and fig. 2 shows a schematic representation of a matrix arrangement of touch control switches, each one as shown in fig. 1 and under control

of a microprocessor.

The touch control switch shown in fig. 1 comprises a dielectric plate G consisting of glass with a single conductive layer A applied to its front side and two similar conductive layers B, C applied to its back side next to each other and superimposed on layer A. An input connector Ise SC is provided for layer B and an output connection SW is provided for layer C, whereby read pulses can be applied to layer B to induce output pulses in layer C as a result of the capacitive coupling between the two layers B, C via layer A. If layer A is affected , the capacitive characteristic of the switch will change, with the consequence that the amplitude of the output pulses falls and triggers a control function in external control circuits which are connected to the connections SC and SW. As described so far, the switch is of conventional design.

However, the switch is further adapted to accommodate an electroluminescent device so that light emitted from an electrically excited phosphor layer P is transmitted forward through the plate G so that it becomes visible to an operator. The conductive layers A, B and C are arranged so that they can transmit light, and are either deposited on the glass in the desired configuration, or are produced by etching a conductive coating on the glass. The connections SC and SW are preferably formed integrally with the conductive layers B and C and in the same manufacturing step.

A mask M of electrically insulating material is then applied to the back of the plate G in such a way that it exposes a symbol-shaped portion of the layer B. The symbol is shown in the example by the letter "S" in fig. 1, and the mask is shown as a layer where the letter "S" has been taken out. Meanwhile, the mask M is preferably applied as a coating to the plate G and the symbol etched out of this to expose the underlying layer B.

A phosphor layer P is then applied to the back of the plate G, or at least to the exposed symbol-shaped portion of the layer B, and an electrode E is arranged in contact with the phosphor in such a way as to cover the symbol-shaped portion of the layer B.

An input connection SL is connected to the electrode

E for applying an illumination control signal to this from external control circuits, whereby the excitation of the phosphor P is controlled, the phosphor P being excited when the potential difference between the layer B and the electrode E exceeds a fixed "illumination threshold". The aforementioned potential difference is produced by the reading pulses and the lighting control signal. As a typical example, positive pulses are applied via input connection SC to layer B, and the illumination control signal applied via input connection SL to electrode E is either a grounded signal that limits the potential across the phosphor so that it is not excited, or it is a negative signal that produces a sufficient potential difference in relation to the positive pulses so that the phosphor is excited and emits light. Thus, the positive pulses can serve both to sense the position of the switch, and to excite the phosphor under control of the lighting control signal.

It will be appreciated that the mask M serves to limit the area of electrical contact between the layer B and the phosphor layer

•P' to thus define a sharp symbol image, and ensure that light images of other components, such as the compound

SC, not being produced. It will also be realized that the electrode E and the phosphor layer P are limited in size so that the conductive layer C does not overlap, since otherwise you would get a capacitive coupling between the layers B and C which would affect the normal switch function in the switch.

Fig. 2 shows a 4 x 4 multiplexed arrangement of switches, each of which is similar to the switch shown in Fig. 1, with input connections SC, SL and output connections SW connected to control circuits comprising a microprocessor F. The switches are shown arranged in rows and columns and with the input connections SC to the four switches in each column connected to a common input terminal SCI, SC2, SC3 or SC4, and with the output connections SW to each of the four switches in each row connected to a common output terminal SW1, SW2, SW3 or SW4.

The microprocessor F has an 8-bit input/output I/Ol with four output connections which are connected via a voltage amplifier ICI to the switch array's four input connections SCI to SC4, and with four input connections which are connected via eh buffer circuit IC2 to the switch array's output connections SWl to SW4. The microprocessor generates a sequence of square read pulses with an amplitude of 5 volts and these are converted to 50 volt pulses by the amplifier ICI and applied to the array input connections SCI to SC4. The resulting output pulses from the connections SW1 to SW4 are sharp, which is due to the capacitive properties of the contact switches, but the fall rate of these pulses is limited due to the high input impedance of the buffer circuit IC2. The amplitude of an output pulse is reduced if a switch is actuated or operated, and it falls below a threshold level which is set in the buffer circuit IC2 so that it does not send any output pulse to the microprocessor. If a switch is not operated, however, the output pulse will cause the buffer circuit IC2 to send out a corresponding output pulse to the microprocessor. Furthermore, the buffer circuit IC2 is designed in such a way that the resulting output pulses which are sent to the microprocessor are mainly square pulses with an amplitude and length equal to the output pulses from the microprocessor. This means that the input and output pulses can be analyzed together in the microprocessor to determine whether any of the switches in the array have been operated.

In an alternative embodiment, the buffer circuit IC2 can be replaced by four comparators each equipped with a first input from the respective output terminals SW1 to SW4, and a second input from a voltage divider which sets a threshold potential for all comparators, which potential corresponds to a level which differentiates between the output pulses from an operated and a non-operated switch. An advantage of this arrangement is that when using the same voltage supply for the voltage divider and the read pulses, greater variations in the supply voltage can be tolerated than with the arrangement comprising the buffer circuit IC2.

During operation, the microprocessor F applies four read pulses to the inputs SCI to SC4 in turn. If the four switches in the column associated with an input are not operated, these send output pulses via outputs SW1 to SW4 back to the microprocessor each time they are read. If, however, one of the switches has been operated, this prevents the passage of a pulse to the output associated with the series of switches to which the relevant switch belongs. Each time each column is read, the microprocessor searches for missing pulses on the respective output connections to see if the corresponding switch in that switch row has been operated. The four reading pulses applied to each column thus read, each in turn, the four switches in the column to see if someone has been operated on, and each switch column is read in turn in the same way.

If an operated switch is identified, the microprocessor F preferably checks the identification before starting a suitable predetermined control operation. The check is performed by reading the entire array of switches as described above a predetermined number of times to see if the switch continues to block the output pulse. The actuation of each switch produces a separate identification code which is stored in the microprocessor on first generation, and is compared with the codes produced during successive control cycles, the appropriate control operation being initiated only after a match has been determined in a predetermined number of successive comparison operations.

As well as the identification of the impact of

a special touch control switch, the microprocessor can identify the simultaneous action of two or more touch control switches and use this to initiate additional control functions.

As well as generating read pulses to sense the state of the switches, the microprocessor generates lighting control signals which are applied to the switches' electrodes E to control the lighting of each individual switch. This is achieved by applying a lighting control signal to all electrodes E of the switches in each row in order and via the respective input terminals SLI to SL4, this occurring in a timed sequence at the same time as the application of pulses to the input terminals SCI to SC4 so that that the lighting of each switch is controlled individually. The lighting control signals are generated by the microprocessor in the required sequence of four outputs from the input/output port 1/02 and pass via an amplifier IC3 to the terminals SLI to SL4. The electrodes E in each row are connected together via their inputs SL and are connected to the respective terminals SLI to SL4.

The input pulses applied to the terminals SCI to SC4, simultaneously with the lighting control signals on the terminals. SLI to SL4, can be read pulses that are analyzed to sense whether any of the switches have been operated or not. Preferably, however, these pulses on the terminals SCI to SC4 can be generated independently of the reading pulses, and the microprocessor controls the sensing of operated switches and the lighting of the switches independently of each other.

The microprocessor must possess instructions which enable it to perform the required sequential input/output operations at a speed sufficient for the functions described above, and a suitable microprocessor is the Fairchild F-8.

The arrangement of switches as shown in fig. 2 is preferably arranged on a single dielectric plate G on which the switches' individual conductive layers A, B, C are applied. It is also advantageous in such a unit construction to provide a common electrode E for each switch row so that only a single input connection SL is required for each row when connected to a respective terminal SLI to SL4. This can be easily achieved in fig. 2 in that the layers B and C are arranged above each other instead of next to each other, and in that a single strip electrode E is arranged which extends along the row across the layers B, but not over the layers C.

Although a square 4x4 array of switches is shown, it will be appreciated that the array may comprise any symmetric or asymmetric array of n groups of m switches with m read inputs each connected to a respective set of said switches and comprising one from each group, n reading outputs that are each connected to all switches in a respective group, and n lighting control inputs that are each connected to all switches in a respective group.

The touch control switch shown and the arrangement of the switches can be arranged in a hermetically sealed housing. Furthermore, a printed circuit board comprising the intermediate connection circuits, such as the circuits ICI, IC2 and IC3, may be arranged on the back of the dielectric plate G.

Claims (7)

1. Touch control switch comprising a dielectric plate (G) on one side of which a first conductive layer (A) is arranged and on the opposite side of which second and third conductive layers (B, C) are arranged which are in a separate, superimposed relationship to the first layer (A), with a respective electrical connection (SC or SW) being arranged to the second and third layers (B, C) for use in detecting operation of the switch with a read signal, the read signal being applied to one connection (SC or SW) and a corresponding, induced signal is extracted from the second connection (SW or SC), characterized in that it further comprises a phosphor layer (P) in contact with the second conductive layer (B), an electrode (E) which is superimposed on the phosphor layer (P), due to an input connection (SL) to the electrode (E) for applying an illumination control signal, the dielectric plate (G) and the first and second conductive layers (A, B) consisting of light-transmitting material so that light passes through it from the phosphor layer tet (P). when this is excited by a potential difference produced by signals on the second conductive layer (B) and the electrode (E). 2. Switch according to claim 1, characterized in that a light-impermeable mask layer (M) is arranged over the second conductive layer (B) so that only a symbol-shaped part of the second layer (B) is uncovered, the preliminary layer (P) being applied in the smallest on the symbol-shaped part of the second layer (B). 3. Switch according to claim 1 or 2, characterized in that the electrode (E) does not cover the third layer (C). 4. Assembly of a number of touch control switches, each of which is as indicated in any of the preceding claims, characterized in that they are arranged in a matrix arrangement with n groups of m switches with m read inputs (SC) each of which is connected to a respective set of the switches comprising one from each group, with n reading outputs (SW) which are each connected to all switches in a respective group, and with n lighting control inputs (SL) which are each connected to the electrodes (E) of all switches in a respective group, a processor (F) being connected to the aforementioned reading and lighting control inputs (SC), (SL) to imprint signals on these to illuminate selected switches, and the processor is further connected to the aforementioned reading outputs (SW) and includes a device for supplying a reading signal to each of the reading inputs (SC ) in sequence and a device for analyzing the signals on the read outputs (SW) at each application of the read signal to determine whether any of the respective switch sets have been operated. 5. Assembly according to claim 4, characterized in that the switches are arranged on a common dielectric plate (G) and the electrodes (E) of the switches in each group are formed by a respective single electrode. 6. Assembly according to claim 4 or 5, characterized in that it comprises a device for supplying the read signal to each read input (SC) a predetermined number of times during each read cycle, so that the processor (F) reads the state of each switch set that said predetermined number of times, and that the processor (F) comprises a reaction device which only reacts if the same signal pattern corresponding to a control function appears on the read outputs (SW) each time. 7. Assembly according to one of claims 4-6, characterized in that "one comprises a device which produces the read signal in the form of a pulse signal so that the read output (SW) of each switch produces an output pulse with reduced amplitude when it has been operated, each read output is coupled to the processor (F) via a circuit (IC2) which sends a pulse to the processor (F) only in response to read output pulses with an amplitude above a predetermined threshold corresponding to the lower limit of the amplitude of read output pulses from a non-operated switch .