DE102013100650A1 - Method for operating touch screen assembly for e.g. mobile telephone, involves deactivating switch in response to force, and activating haptic feedback device to displace contact surface in response to deactivation of switch in vibration - Google Patents

Abstract

The method involves monitoring a switch (52) e.g. force-sensitive resistor, to determine whether the switch is provided in an activated state in which a contact force is not exerted on a contact surface or in a deactivated state in which the contact force is exerted on the contact surface. The contact force is received at the contact surface. The switch is deactivated in response to the received contact force at the contact surface. A haptic feedback device (44) is activated to displace the contact surface in response to deactivation of the switch in vibration. The haptic feedback device is an eccentric rotary mass vibrator and a piezoelectric element.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of US Provisional Patent Application Serial No. 61 / 591,477, filed on Jan. 27, 2012, and US Provisional Patent Application Serial No. 61 / 591,454, filed on Jan. 27, 2012, the entire contents of which are incorporated herein by reference the present subject matter is included.

GENERAL PRIOR ART

1. Field of the invention

The present invention relates generally to touch assemblies, and more particularly to methods of operating touch assemblies.

2. Related prior art

Mobile phones, laptop computers, tablet computers, vehicles, etc. are increasingly being equipped with touch screen assemblies. In vehicles, touch screens are often used to control, for example, a navigation system; a radio; a heating, ventilation and air conditioning system (HVAC system); etc. used. Typical touch screen assemblies are configured to be actuated in response to a person's finger touching or pushing an area of a touch screen monitor and applying a touch force to the touch screen assembly.

Typical touch screen assemblies have touch screen monitors mounted in the vehicle that remain fixed when pressed and operated in response to a touch force even when a person touches the touch screen monitor very lightly. This often leads to unwanted activations. Some manufacturers of touch screen assemblies have attempted to solve this problem by observing the touch force applied to the surface of the touch screen monitor by means of a dynamometer that operates the touch screen assembly only in response to a touch force exceeding a predetermined threshold. Occasionally, a haptic feedback means is provided to provide some sort of feedback, such as vibration, to the person who has applied the touch force that exceeds the pre-established threshold to teach the person about proper activation of the touch screen monitor , The sensors used in many known touch screen assemblies are high resolution force gauges that are also very expensive.

There is a continuing need for a less expensive system that protects against inadvertent actuation by being actuated only in response to the touch force when the actuation is intended.

BRIEF SUMMARY OF THE INVENTION

One aspect of the present invention provides a method of operating a touch assembly having a touch pad, a haptic feedback device, and at least one switch. The method includes the step of monitoring the at least one switch to determine if it is in an activated state, indicating that no touch force is applied to the touch pad, or in a disabled state indicating that a contact force is exerted on the contact surface. The method continues with the step of receiving a touch force on the touch surface. The method continues with the step of disabling the switch in response to the touch surface receiving the touch force. The method continues with the step of activating the haptic feedback device to vibrate the touch surface in response to the switch being deactivated, that is, switching from the activated configuration to the deactivated configuration.

Another aspect of the present invention includes adjusting the monitoring of the at least one switch in response to the at least one switch being in a deactivated state to prevent continuous deactivation of the at least one switch by the haptic feedback device. In other words, the touch screen assembly automatically prevents the haptic feedback device from self-activating.

According to another aspect of the invention, the step of activating the haptic feedback device takes a certain time, and the step setting the monitoring of the at least one switch is further defined as delaying the monitoring of the at least one switch for a longer duration.

In accordance with another aspect of the present invention, the step of activating the haptic feedback device occurs over a predetermined number of cycles and further includes the step of counting the cycles from the haptic feedback device, wherein the step of setting the monitoring the at least one switch is further defined as delaying the monitoring of the at least one switch until the predetermined number of cycles have been counted.

According to another aspect of the present invention, the step of setting the monitoring of the at least one switch is further defined as measuring a signal generated by the switch and allowing the haptic feedback device to be reactivated only if when the signal generated by the at least one switch exceeds a predetermined threshold.

Another aspect of the present invention relates to a method of operating a touch assembly having a touch pad, a base, a haptic feedback device, and at least one switch that is switchable between an activated configuration and a deactivated configuration, wherein the at least one switch is incorporated in the activated configuration is preset. The method includes the step of receiving a touch force on the interface to move the interface relative to the base. The method continues with the step of measuring the touch force on the interface. The method continues with the step of switching the at least one switch to the deactivated configuration in response to the contact surface moving relative to the base. The method continues with the step of transmitting a signal only in response to measuring the location of the touch force and having the at least one switch in the deactivated configuration. The method is advantageous because it prevents inadvertent actuation of the touch assembly due to vibration or accidental stripping of the interface.

According to another aspect of the present invention, the step of switching the at least one switch from the activated configuration to the deactivated configuration is further defined as opening an electrical circuit. The at least one switch may be a force-sensitive resistor.

According to another aspect of the present invention, the step of switching the at least one switch out of the activated configuration and into the deactivated configuration is further defined as changing the capacitance of the capacitive sensor.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other features and advantages of this invention will be readily appreciated as the same becomes better understood by reference to the following detailed description taken in conjunction with the accompanying drawings; show it:

1 a plan view of a first embodiment of the contact assembly;

2 a cross-sectional view of the first embodiment of the contact assembly taken along the line 1-1 of 1 showing a plurality of switches in an activated state;

3 another cross-sectional view of the first embodiment of the touch assembly, showing the plurality of switches in a deactivated state;

4 a perspective view of a base and a plurality of switches of the embodiment of 1 ;

5 a cross-sectional view of an alternative embodiment of the contact assembly; and

6 a perspective view of a base and a plurality of switches of the alternative embodiment of the contact assembly.

DESCRIPTION OF THE POSSIBLE EMBODIMENTS

Referring to the drawings, wherein like reference numbers indicate corresponding parts throughout the several views, FIG 1 - 3 a first exemplary touch assembly 20 generally shown. As in 1 shows the first exemplary touch assembly 20 a touch screen monitor 22 with a surface 24 for receiving a touch force and a housing 26 on, the touchscreen monitor 22 contains and carries. Although in the embodiments, it is considered a touch screen monitor 22 It should be noted that the contact assembly 20 may have any type of touch surface configured to receive a touch force, that is, it need not be a monitor.

As in 1 The exemplary touchscreen monitor has shown 22 and the case 26 in the first embodiment, a generally rectangular shape. On the touch screen monitor 22 it can be any type of flat panel monitor you want, including For example, a liquid crystal display (LCD) monitor, a light emitting diode (LED) monitor or a plasma monitor. Although not shown, preferably a grid is on a bottom of the touch screen monitor 22 arranged to measure the position of the contact force. In particular, the grid is configured to have coordinates (such as X and Y coordinates) of the contact force on the surface 24 of the touch screen monitor 22 to determine. The housing 26 may be any desired shape and may be formed of any desired material or combination of materials, including, for example, polymeric, metallic or composite materials.

Referring to 2 shows the case 26 in the exemplary embodiment, an upper cover 28 (or a bezel) and a bottom cover 30 which are interconnected by any means such as fasteners, adhesives, etc. Inside the case 26 is between the touchscreen monitor 22 and the lower cover 30 One Base 32 arranged, and a printed conductor (or wire) plate (main PCB 36 ) is inside the housing 26 between the base 32 and the lower cover 30 arranged. The main PCB 36 has, inter alia, at least one microprocessor 38 which is in electrical connection with the touch screen monitor 22 stands in response to the touch screen monitor 22 a force measures signals. As shown, the base is 32 of the embodiment larger than the touch screen monitor 22 and extends on opposite sides of the touch screen monitor 22 outward. Several compression springs 40 are between the touchscreen monitor 22 and the base 32 arranged to the touch screen monitor 22 in a rest position on the top cover 28 of the housing 26 and at a certain distance or with a certain gap spaced from the base 32 pretension. In the exemplary embodiment, the compression springs 40 Body made of elastic material. However, it should be understood that any desired type of spring including helical springs may alternatively be used. The stiffness or spring constant of the compression springs 40 determines, at least in part, the touch force needed to use the touch screen monitor 22 to disconnect the contact with the top cover 28 of the housing 26 to the base 32 to move.

Several generally pill-shaped stops 42 are at the base 32 in the gap between the base 32 and the touch screen monitor 22 appropriate. The attacks 42 have a height that is less than the gap between the base 32 and the touch screen monitor 22 is about the movement of the touchscreen monitor 22 relative to the base 32 and the case 26 limit. In other words, the attacks 42 provide an anchor point beyond which the movement of the touch screen monitor 22 is restricted. The attacks 42 are preferably formed of an elastic material around the touch screen monitor 22 to protect against damage caused by excessive contact force. The attacks 42 are preferably dimensioned to be the touch screen monitor 22 restrict to about 0.25 mm.

A haptic feedback device 44 is on the touch screen monitor 22 coupled to a person's touch the touch screen monitor 22 exercise to provide haptic feedback. In the first embodiment of the contact assembly 20 , this in 2 and 3 is shown is the haptic feedback device 44 is an eccentric rotating mass (ERM) vibrator 44 with an electric motor 50 , at whose output an unbalanced mass 48 is coupled. The ERM vibrator 44 is in electrical communication with the microprocessor 38 on the main PCB 36 that the actuation of the ERM vibrator 44 controls. When the electric motor 50 in operation by the microprocessor 38 is pressed, the unbalanced mass 48 rotated to create a vibration in the touch screen monitor 22 and is perceived by the person to inform the person that the touch screen monitor 22 was pressed. It is understood that other types of haptic feedback devices may alternatively be used to provide feedback to the person.

The touch assembly 20 also has several sensors connected to the touch screen monitor 22 are coupled and configured to measure whether a person is using the touch screen monitor 22 deliberately operated. In particular, the sensors of the first exemplary touch assembly 20 around switch 52 that are biased into an activated configuration and only in response to the touch screen monitor 22 from the rest position to the base 32 switch to a disabled configuration. The switches 52 stand with the microprocessor 38 on the main PCB 36 in communicating connection, such that disabling one of the switches 52 the microprocessor 38 signals the haptic feedback device 44 to press. The switches 52 All of them can be serially wired together, such that activating one of the switches 52 causes the electrical circuit to open, or alternatively may be wired parallel to one another.

How best in 4 shown are the switches 52 . 54 at the touch assembly 20 of first embodiment force measuring resistors (KMW 52 ) and are at the four corners of the base 32 on the side of the base 32 opposite the touch screen monitor (not shown in this figure). Referring again to 2 , is a pressure piece 56 effective on the touch screen monitor 22 coupled and extends through the base 32 to the side opposite to the touch screen monitor 22 , Preloading the touch screen monitor 22 away from the base 32 against the top cover 28 causes the pressure piece 56 against the KMW 52 is preloaded with a first force, which causes the KMW 52 have a first, very low resistance. When a touch force on the surface 24 of the touch screen monitor 22 is exercised to the touch screen monitor 22 To move, this lowers the force of one or more pushers 56 on the KMW 52 exercise and increase the resistance of the KMW 52 , When the pressure piece 56 completely from the associated KMW 52 triggers (such as in 3 shown), the resistance of the associated KMW decreases 52 strong, which practically opens an electrical circuit. Opening this circuit brings the microprocessor 38 to the ERM vibrator 44 to activate the touch screen monitor 22 vibrate to provide haptic feedback to the person.

In the first embodiment, the microprocessor 38 , the ERM vibrator 44 and the KMW 52 all over wires 34 electrically connected to each other. However, it will be understood that these components can alternatively communicate wirelessly with each other.

Referring to 5 Here is an alternative embodiment of the touch assembly 120 generally, wherein like numerals are separated by a factor of 100 to indicate elements corresponding to the embodiment described above. The second embodiment is similar to that discussed above with the exception that the haptic feedback device 144 a piezoelectric element 144 instead of the ERM vibrator discussed above 44 is and the switches 152 capacitive sensors 152 instead of the KMW discussed above 52 are. The piezoelectric element 144 is configured to expand or contract when an electric current flows through it. Preferably, the microprocessor 138 configured to receive an alternating current through the piezoelectric element 144 which causes it to expand and contract in a cyclic manner, which makes the touch screen monitor 122 is put into vibration. Adjusting the amplitude and frequency of the AC current applied to the piezoelectric element 144 can also change the perception of vibration for the person. Accordingly, the touch assembly could 120 be configured to provide feedback when the person occupies a first position of the touch screen monitor 122 presses, and another feedback when a person changes the location of the touchscreen monitor 122 suppressed. The capacitive sensors 152 are configured to change their capacity in response to a change in force on the plungers 156 is exercised. In operation, the change in the capacity of the microprocessor 138 measured, which is the piezoelectric element 144 Activated to provide haptic feedback in response to that of the capacitive sensors 152 measured capacity exceeds a pre-determined threshold capacity. The thickness of the capacitive sensors 152 is in 5 exaggerated, because, as in 6 shown the capacitive sensors 152 this alternative embodiment in the base 132 are installed. It is understood that it is the switch 52 . 152 and the haptic feedback devices 44 . 144 may be numerous devices that differ from those shown in the embodiments.

Another aspect of the present invention is a method of operating a touch assembly 20 . 120 with a touchpad and a haptic feedback device 44 . 144 and at least one switch 52 . 152 which is adjustable in an activated state and a deactivated state. The at least one switch 52 . 152 is configured to be in the activated state when no touch force is applied to the touch surface, and to switch to the deactivated state in response to the application of a touch force to the touch surface. The method includes the step of monitoring the state of the at least one switch 52 . 152 on. The method continues with the step of receiving a touch force on the touch surface. The method then proceeds to the step of disabling the switch 52 . 152 in response to the touch surface receiving the touch force. The method continues with the step of activating the haptic feedback device 44 . 144 continues to contact surface in response to the deactivation of the switch 52 . 152 to vibrate. In other words, it is the deactivation and not the activation of the at least one switch 52 . 152 that activate the haptic feedback device 44 . 144 triggers. The switch or switches 52 . 152 can KMW 52 , capacitive sensors 152 or any other types of switches. The haptic feedback device 44 . 144 can be an ERM vibrator 44 , a piezoelectric element 144 or any desired type of haptic feedback device.

The method may include the steps of adjusting the monitoring of the at least one switch 52 . 152 in response, continue that at least one switch 52 . 152 is in a deactivated state to a continuous deactivation of the at least one switch 52 . 152 through the haptic feedback device 44 . 144 to prevent. In other words, the touch assembly 20 . 120 Automatically prevents the haptic feedback device 44 . 144 enters a loop where it turns off. of the switch 52 . 152 self-activated.

In one embodiment, this is achieved by the at least one switch 52 . 152 is monitored for a duration greater than the duration of activation of the haptic feedback device 44 . 144 is. If the haptic feedback device 44 . 144 For example, it is configured to be activated for a quarter second in response to the switch 52 . 152 switches to the disabled configuration, holds the touch assembly 20 . 120 automatically monitoring the state of the at least one switch 52 . 152 for more than a quarter second before the normal monitoring of the condition of the at least one switch 52 . 152 is resumed.

In another embodiment, preventing the self-activation of the haptic feedback device 44 . 144 achieved by monitoring the at least one switch 52 . 152 is delayed until a predetermined number of vibrations has been measured. If the haptic feedback device 44 . 144 For example, if configured to be activated for twenty cycles, the touch screen assembly counts the cycles and keeps monitoring the state of the at least one switch 52 . 152 until the twenty cycles were counted.

In another embodiment, preventing the self-activation of the haptic feedback device 44 . 144 achieved by a signal coming from the switch 52 . 152 is generated, is measured, and the reactivation of the haptic feedback is allowed only when the signal from the at least one switch 52 . 152 is generated exceeds a predetermined threshold. For example, if the at least one sensor is a force sensitive resistor, the touch screen assembly may automatically stop monitoring the state of the at least one force sensitive resistor until its resistance falls below a predetermined level.

Another aspect of the present invention also relates to a method of operating a touch assembly 20 . 120 with a touch screen, a base 32 . 132 , a haptic feedback device 44 . 144 and at least one switch 52 . 152 , The at least one switch 52 . 152 can be switched between an activated configuration and a deactivated configuration and is preset to the activated configuration. The method continues with the step of receiving a touch force on the touch surface to move the touch surface. The method continues with the step of measuring the contact force at the interface. The method further comprises the step of switching the at least one switch 52 . 152 into the disabled configuration in response to the contact area relative to the base 32 . 132 emotional. The method continues with the step of transmitting a signal only in response to measuring the location of the touch force and that the at least one switch 52 . 152 is in the deactivated state. The signal coming from the touch module 20 can be transmitted, for example, to trigger the haptic feedback device 44 . 144 or to accomplish any desired action. This is beneficial since it precludes accidental actuation of the touch assembly 20 . 120 protects. When the touch assembly 20 . 120 is put into vibration, for example, the at least one switch 52 . 152 disabled, but the touch assembly 20 . 120 is not activated because no point of contact force has been measured. Alternatively, if a person touches the touchpad accidentally, a location is measured, but the touch assembly 20 . 120 is not actuated because the at least one switch 52 . 152 not deactivated.

Although the invention has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, numerous modifications may be made to the teachings of the invention to achieve adaptation to a particular situation or material without departing from the essential scope thereof. It is therefore intended that the invention not be limited to the particular embodiment disclosed as best mode for carrying out this invention, but includes all embodiments falling within the scope of the appended claims.

Claims (13)

A method of operating a touch assembly having a touchpad and a haptic feedback device and at least one switch, comprising the steps of: monitoring the at least one switch to determine whether it is in an activated state indicating that no touch force is applied to the touch surface or in a deactivated state indicating that a touch force is exerted on the touch surface; Receiving a touch force at the contact surface; Deactivating the switch in response to the touch surface receiving the touch force; and activating the haptic feedback device to vibrate the interface in response to deactivating the switch. The method of claim 1, further comprising a step of adjusting monitoring of the at least one switch in response to the at least one switch being in a deactivated state to prevent continuous deactivation of the at least one switch by the haptic feedback device. The method of claim 2, wherein the step of activating the haptic feedback device takes a certain time, and wherein the step of setting the monitoring of the at least one switch is further defined as delaying monitoring of the at least one switch for a longer duration. The method of claim 2, wherein the step of activating the haptic feedback device occurs over a predetermined number of cycles, and further comprising the step of counting the cycles from the haptic feedback device, and wherein the step of adjusting the monitoring of the haptic feedback device at least one switch is further defined as delaying monitoring of the at least one switch until the predetermined number of cycles have been counted. The method of claim 2, wherein the step of adjusting the monitoring of the at least one switch is further defined as measuring a signal generated by the switch and allowing the haptic feedback device to be reactivated only when the signal that is generated by the at least one switch exceeds a predetermined threshold. A method of operating a touch assembly having a touch surface and a base and a haptic feedback device and at least one switch that can be switched between an activated configuration and a deactivated configuration, wherein the at least one switch is preset to the activated configuration, comprising the steps of : Receiving a touch force on the mating surface to move the mating surface relative to the base; Measuring the contact force at the contact surface; Switching the at least one switch into the deactivated configuration in response to the contact surface moving relative to the base; and Transmitting a signal only in response to the location of the touch force being measured and the at least one switch being in the deactivated configuration. The method of claim 6, further comprising a haptic feedback device, and wherein the signal activates the haptic feedback device to vibrate the interface. The method of claim 7, wherein the haptic feedback device is an eccentrically rotating mass vibrator. The method of claim 7, wherein the haptic feedback device is a piezoelectric element. The method of claim 6, wherein the at least one switch is at least one force sensitive resistor. The method of claim 10, wherein the step of switching the at least one switch from the activated configuration to the deactivated configuration is defined as opening an electrical circuit. The method of claim 6, wherein the at least one switch is a capacitive sensor. The method of claim 12, wherein the step of switching the at least one switch from the activated configuration to the deactivated configuration is defined as changing the capacitance of the capacitive sensor.

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