CN205318349U - Tactile feedback device, Touch display panel and touch display device - Google Patents

Abstract

The utility model provides a tactile feedback device, touch display panel and touch display device, but this tactile feedback device is including deformation structure, controller and driver, but the deformation structure includes a plurality of deformation units, the controller be used for according to the positional information of user touch to the driver sends control signal, the driver with but the deformation structure the controller links to each other, the driver is used for the basis the control signal drive that the controller sent but in the deformation structure with the deformation monogenesis that the positional information of user's touch corresponds deforms. The utility model provides a tactile feedback device, when the user touched the touch -sensitive screen, the controller sent control signal according to the position of user's touch to the driver, and the driver can control bit in the deformation monogenesis deformation of touch position after receiving control signal to touch to the user produces corresponding feedback, effectively improves the touch -control and experiences alternately.

Description

Haptic feedback devices, touch display panel and touch display unit

Technical field

This utility model relates to display field, particularly relates to a kind of haptic feedback devices, touch display panel and touch display unit.

Background technology

Along with developing rapidly of Display Technique, touch screen has been widely used in the products such as smart mobile phone, panel computer, all-in-one, control terminal, but existing touch screen technology lacks experience interactivity, and Consumer's Experience is poor.

Utility model content

(1) to solve the technical problem that

The technical problems to be solved in the utility model is: provide a kind of haptic feedback devices, touch display panel and touch display unit, it is possible to increase touch-control interactive experience.

(2) technical scheme

For solving above-mentioned technical problem, the technical solution of the utility model provides a kind of haptic feedback devices, including can deformation structure, controller and driver;

Described deformation structure can include multiple deformation unit;

Described controller sends control signal for the positional information touched according to user to described driver;

Described driver can deformation structure, described controller be connected with described, and described driver drives for the control signal sent according to described controller and described can deform upon by the deformation unit corresponding with the positional information that described user touches in deformation structure.

Preferably, the plurality of deformation unit is matrix arrangement.

Preferably, described deformation unit includes the first electrode, the second electrode and the electrostriction material between described first electrode and described second electrode, when applying voltage between described first electrode and described second electrode, described deformation unit deforms upon.

Preferably, also include a plurality of first holding wire, a plurality of secondary signal line and with each deformation unit the first film transistor one to one;

Wherein, each the first holding wire is connected with the source electrode of the first film transistor corresponding to string deformation unit, each secondary signal line is connected with the grid of the first film transistor corresponding to a line deformation unit, the drain electrode of the first film transistor that the first electrode of each deformation unit is corresponding is connected, the second electrode ground connection of each deformation unit;

For each the first film transistor, when the secondary signal line being connected with its grid is applied in scanning voltage signal, and the first holding wire being connected with its source electrode is applied in drive voltage signal simultaneously, the deformation unit of its correspondence deforms upon.

Preferably, described driver includes driving voltage module, scanning voltage module and MUX;

Described driving voltage module is used for producing described drive voltage signal;

Described scanning voltage module is used for producing described scanning voltage signal;

Described MUX is for inputting corresponding secondary signal line according to described control signal by described scanning voltage signal, simultaneously by the first corresponding for the input of described drive voltage signal holding wire, to drive the deformation unit corresponding with the positional information of described user touch to deform upon.

Preferably, described MUX include with each article of the first holding wire the second thin film transistor (TFT) one to one and with each article of secondary signal line the 3rd thin film transistor (TFT) one to one, the source electrode of described second thin film transistor (TFT) is connected with the outfan of described driving voltage module, and the source electrode of described 3rd thin film transistor (TFT) is connected with the outfan of described scanning voltage module.

Preferably, described drive voltage signal is ac voltage signal.

Preferably, described electrostriction material includes piezoelectric ceramics.

For solving above-mentioned technical problem, this utility model additionally provides a kind of touch display panel, including above-mentioned haptic feedback devices.

Preferably, also include touch screen and display floater, described touch screen is arranged on the display side of described display floater, described deformation structure can be arranged on the side of described touch screen described display floater dorsad, and described controller obtains, by described touch screen, the positional information that described user touches.

For solving above-mentioned technical problem, this utility model additionally provides a kind of touch display unit, including above-mentioned touch display panel.

(3) beneficial effect

The haptic feedback devices that this utility model provides, when user touches touch screen, the position that controller touches according to user sends control signal to driver, driver can control to be positioned at the deformation unit of touch location upon the reception of control signals and deform upon, thus the touch of user is produced corresponding feedback, it is effectively improved touch-control interactive experience.

Accompanying drawing explanation

Fig. 1 is the schematic diagram of a kind of haptic feedback devices that this utility model embodiment provides;

Fig. 2 is the schematic diagram of a kind of deformation unit arrangement that this utility model embodiment provides;

Fig. 3 is the schematic diagram of a kind of deformation unit that this utility model embodiment provides;

Fig. 4 is the schematic diagram of the another kind of haptic feedback devices that this utility model embodiment provides;

Fig. 5 is the schematic diagram of another haptic feedback devices that this utility model embodiment provides;

The schematic diagram of a kind of driver that Fig. 6 this utility model embodiment provides;

Fig. 7 is the schematic diagram of a kind of touch display unit that this utility model embodiment provides.

Detailed description of the invention

Below in conjunction with drawings and Examples, detailed description of the invention of the present utility model is described in further detail. Following example are used for illustrating this utility model, but are not limited to scope of the present utility model.

Fig. 1 is the schematic diagram of a kind of haptic feedback devices that this utility model embodiment provides, and this haptic feedback devices includes can deformation structure 100, controller 200 and driver 300;

Described deformation structure 100 can include multiple deformation unit;

Described controller 200 sends control signal for the positional information touched according to user to described driver;

Described driver 300 can deformation structure 100, described controller 200 be connected with described, and described driver 300 drives for the control signal sent according to described controller and described can deform upon by the deformation unit corresponding with the positional information that described user touches in deformation structure.

The haptic feedback devices that this utility model embodiment provides, when user touches touch screen, the position that controller touches according to user sends control signal to driver, driver can control to be positioned at the deformation unit of touch location upon the reception of control signals and deform upon, thus the touch of user is produced corresponding feedback, it is effectively improved touch-control interactive experience.

Such as, can multiple deformation unit 110 in deformation structure 100 can the arrangement in matrix as shown in Figure 2, when the touch of user being detected, it is possible to deform upon by controlling to be positioned at the deformation unit of this touch location, thus user being provided corresponding feedback.

The haptic feedback devices that this utility model embodiment provides, when the touch of user being detected, controller applies to drive signal to corresponding deformation unit by driver, deformation unit can deform upon under the effect of this driving signal, such as, deformation unit can include electrostriction material, electrostriction material is a kind of material with electromechanical Coupling, it can produce certain deformation under the fall out effect of external electric field, and square being directly proportional of the deformation of its generation and electric field intensity size;

Such as, the structure of deformation unit can be as shown in Figure 3, deformation unit includes the first electrode 111, second electrode 112 and the electrostriction material 113 between described first electrode 111 and described second electrode 112, such as, this electrostriction material can be piezoelectric ceramics, the shape of the electrostriction structure formed by electrostriction material can be cuboid strip bar structure, when applying voltage between the first electrode and the second electrode, corresponding deformation is there is in this deformation unit under the effect of voltage, form corresponding feedback, such as, for the deformation unit shown in Fig. 3, the second electrode 112 ground connection can be made, driver is by applying voltage signal to the first electrode thus realizing the control to deformation unit,

Preferably, driver generates ac voltage signal to drive deformation unit to deform upon according to described control signal, such as, for the deformation unit shown in Fig. 3, the second electrode ground connection therein, when applying ac voltage signal to the first electrode, the shape of electrostriction structure can change, and owing to ac voltage signal frequency is higher, enable user to experience the sensation of vibration and surface irregularity when touching, thus improving touch-control interactive experience further.

Being the schematic diagram of another kind of haptic feedback devices that this utility model embodiment provides referring to Fig. 4, Fig. 4, this haptic feedback devices includes can deformation structure 100, controller 200 and driver 300;

Deformation structure 100 can include the first electrode layer 101, the second electrode lay 102 and the electrostrictive layer 103 formed between the first electrode layer 101 and the second electrode lay 102 by electrostriction material, wherein, first electrode layer 101 includes the first electrode of multiple deformation unit, the second electrode lay 102 includes the second electrode of multiple deformation unit, and electrostrictive layer 103 includes the electrostriction structure of multiple deformation unit;

Such as, for realize to above-mentioned can the control of deformation structure, can be as shown in Figure 5, multiple first electrodes 111 in the first electrode layer 101 are made mutually to separate and the arrangement in matrix, and a plurality of first holding wire (... .SLn, SLn+1, SLn+2, SLn+3....) extended in a first direction is set, a plurality of secondary signal line that extends in a second direction (... .GLn, GLn+1, GLn+2....) and with each deformation unit the first film transistor 114 one to one, first direction and second direction can be mutually perpendicular to;

Wherein, each the first holding wire is connected with the source electrode of the first film transistor corresponding to string deformation unit, each secondary signal line is connected with the grid of the first film transistor corresponding to a line deformation unit, the drain electrode of the first film transistor that the first electrode of each deformation unit is corresponding is connected, the second electrode ground connection of each deformation unit;

For each the first film transistor, when the secondary signal line being connected with its grid is applied in scanning voltage signal, and the first holding wire being connected with its source electrode is applied in drive voltage signal simultaneously, the deformation unit of its correspondence deforms upon;

In addition, for electrostrictive layer 103, multiple electrostriction structure therein can be interconnected (namely electrostrictive layer is a flood electrostriction film), can also mutually separate (the pattern that electrostrictive layer employing is identical with the first electrode layer, including multiple mutual separations and in matrix arrangement electrostriction structure), identical, for the second electrode lay, multiple second electrode therein can be interconnected (namely the second electrode lay is a flood conductive film), can also mutually separate (the pattern that namely the second electrode lay employing is identical with the first electrode layer, including multiple mutual separations and in matrix arrangement the second electrode), first electrode layer and the second electrode lay can all adopt transparent conductive material (such as ITO) to be formed, the size of the deformation unit formed and number can be designed according to the size of display floater and required precision,

Described controller 200 sends control signal for the positional information touched according to user to described driver;

Described driver 300 drives for the control signal sent according to described controller and described can deform upon by the deformation unit corresponding with the positional information that described user touches in deformation structure;

Specifically, for the haptic feedback devices that this utility model embodiment provides, when controller gets the touching position information of user, controller sends control signal according to this touching position information to driver, this control signal includes the positional information (such as coordinate information) of the deformation unit corresponding with this touching position information, driver is after receiving this control signal, scanning voltage signal is applied to the secondary signal line corresponding with this deformation unit, the first film transistor making this deformation unit corresponding is in the conduction state, apply drive voltage signal to the first holding wire corresponding with this deformation unit simultaneously, thus changing the electromotive force of the first electrode of this deformation unit, voltage is produced between its first electrode and second electrode, and then drive this deformation unit to deform upon, when there being multiple point touching, controller can pass through the deformation unit of driver sequential scan respective regions, the deformation unit being positioned at touch location is driven to deform upon one by one,

Such as, driver 300 can as shown in Figure 6, and it includes MUX 310, driving voltage module 320, scanning voltage module 330;

Wherein, described driving voltage module 320 is used for producing described drive voltage signal;

Described scanning voltage module 330 is used for producing described scanning voltage signal;

Described MUX 310 is for inputting corresponding secondary signal line according to described control signal by described scanning voltage signal, simultaneously by the first corresponding for the input of described drive voltage signal holding wire, to drive the deformation unit corresponding with the positional information of described user touch to deform upon;

Such as, as shown in Figure 6, described MUX 310 include with each article of the first holding wire the second thin film transistor (TFT) 311 one to one and with each article of secondary signal line the 3rd thin film transistor (TFT) 312 one to one, the source electrode of described second thin film transistor (TFT) is connected with the outfan of described driving voltage module, and the source electrode of described 3rd thin film transistor (TFT) is connected with the outfan of described scanning voltage module;

For above-mentioned driver, after driver receives the control signal that controller sends, corresponding second thin film transistor (TFT) of control can be passed through and the 3rd thin film transistor (TFT) is in the conduction state, make drive voltage signal that driving voltage module 320 produces and the scanning voltage signal that scanning voltage module 330 produces be respectively written into corresponding first holding wire and secondary signal line, and then make the deformation unit being positioned at touch location deform upon;

In addition, for realizing MUX being carried out overall control, the 4th thin film transistor (TFT) can also be set up in above-mentioned MUX, such as, the source electrode that can make the 4th thin film transistor (TFT) connects the outfan of driving voltage module, drain electrode connects the source electrode of each the second thin film transistor (TFT), and when the 4th thin film transistor (TFT) and corresponding second thin film transistor (TFT) and the 3rd thin film transistor (TFT) are both turned on, corresponding deformation unit just can deform upon.

This utility model additionally provides a kind of touch display panel, including above-mentioned haptic feedback devices

Preferably, above-mentioned touch display panel also includes touch screen and display floater, described controller obtains, by described touch screen, the positional information that described user touches, described touch screen is arranged on the display side of described display floater, described deformation structure can be arranged on the side of described touch screen described display floater dorsad.

This utility model embodiment further provides a kind of touch display unit, including above-mentioned touch display panel. The touch display unit that this utility model embodiment provides can be any product with display function or the parts such as note-book computer display screen, display, TV, DPF, mobile phone, panel computer.

Referring to Fig. 7, Fig. 7 is the schematic diagram of a kind of touch display unit that this utility model embodiment provides, this display device includes above-mentioned haptic feedback devices and TLCM structure, wherein, TLCM structure includes touch screen 400 and display floater 500, and can deformation structure 100, touch screen 400 and display floater 500 three's stacking the arranging of haptic feedback devices, namely touch screen 400 is arranged on the display side of display floater 500, deformation structure 100 can be arranged on the side of touch screen 400 display floater 500 dorsad;

When user touches this display device, controller detects, by touch screen 400, the positional information that user touches, then the positional information according to the touch of detection sends control signal to driver, driver applies drive voltage signal to the deformation unit being positioned at touch location upon the reception of control signals, deformation unit is made to deform upon, thus the touch of user is produced corresponding feedback;

In addition, when deformation unit adopts electrostriction material, the drive voltage signal of its applying can be adopted ac voltage signal by driver, when electrostriction material loads suitable ac voltage signal, its length in vertically displayed panel direction has trickle change, owing to AC signal frequency is higher, user is enable to experience the sensation of vibration and surface irregularity when touching, thus improving touch-control interactive experience further, reach the purpose of augmented reality (AugmentedReality is called for short AR).

Preferably, the all right integrated touch of above-mentioned controller and presentation control function, such as, referring to Fig. 7, this controller includes the first interface 210 for receiving video signal, for connecting the second interface 220 of described driver and for connecting the 3rd interface 230 of described touch screen 400 and described display floater 500, described controller is additionally operable to control according to the video signal that described first interface receives the image of described display floater and shows, such as, this controller and driver can be arranged on printed substrate (pcb board).

Additionally, this utility model embodiment further provides a kind of sense of touch feedback method, including:

Controller obtains the positional information that user touches;

The positional information that controller touches according to user sends control signal to driver;

The control signal that driver sends according to described controller drives and can deform upon by the deformation unit corresponding with the positional information that described user touches in deformation structure.

Preferably, described deformation unit includes the first electrode, the second electrode and the electrostriction material between described first electrode and described second electrode, when applying voltage between described first electrode and described second electrode, described deformation unit deforms upon.

Preferably, described driver generates ac voltage signal to drive deformation unit to deform upon according to described control signal.

Embodiment of above is merely to illustrate this utility model; and be not limitation of the utility model; those of ordinary skill about technical field; when without departing from spirit and scope of the present utility model; can also make a variety of changes and modification; therefore all equivalent technical schemes fall within category of the present utility model, and scope of patent protection of the present utility model should be defined by the claims.

Claims (11)

1. a haptic feedback devices, it is characterised in that including can deformation structure, controller and driver;

Described deformation structure can include multiple deformation unit;

Described controller sends control signal for the positional information touched according to user to described driver;

Described driver can deformation structure, described controller be connected with described, and described driver drives for the control signal sent according to described controller and described can deform upon by the deformation unit corresponding with the positional information that described user touches in deformation structure.

2. haptic feedback devices according to claim 1, it is characterised in that the plurality of deformation unit is matrix arrangement.

3. haptic feedback devices according to claim 1, it is characterized in that, described deformation unit includes the first electrode, the second electrode and the electrostriction material between described first electrode and described second electrode, when applying voltage between described first electrode and described second electrode, described deformation unit deforms upon.

4. haptic feedback devices according to claim 3, it is characterised in that also include a plurality of first holding wire, a plurality of secondary signal line and with each deformation unit the first film transistor one to one;

Wherein, each the first holding wire is connected with the source electrode of the first film transistor corresponding to string deformation unit, each secondary signal line is connected with the grid of the first film transistor corresponding to a line deformation unit, the drain electrode of the first film transistor that the first electrode of each deformation unit is corresponding is connected, the second electrode ground connection of each deformation unit;

For each the first film transistor, when the secondary signal line being connected with its grid is applied in scanning voltage signal, and the first holding wire being connected with its source electrode is applied in drive voltage signal simultaneously, the deformation unit of its correspondence deforms upon.

5. haptic feedback devices according to claim 4, it is characterised in that described driver includes driving voltage module, scanning voltage module and MUX;

Described driving voltage module is used for producing described drive voltage signal;

Described scanning voltage module is used for producing described scanning voltage signal;

Described MUX is for inputting corresponding secondary signal line according to described control signal by described scanning voltage signal, simultaneously by the first corresponding for the input of described drive voltage signal holding wire, to drive the deformation unit corresponding with the positional information of described user touch to deform upon.

6. haptic feedback devices according to claim 5, it is characterized in that, described MUX include with each article of the first holding wire the second thin film transistor (TFT) one to one and with each article of secondary signal line the 3rd thin film transistor (TFT) one to one, the source electrode of described second thin film transistor (TFT) is connected with the outfan of described driving voltage module, and the source electrode of described 3rd thin film transistor (TFT) is connected with the outfan of described scanning voltage module.

7. haptic feedback devices according to claim 4, it is characterised in that described drive voltage signal is ac voltage signal.

8. according to the arbitrary described haptic feedback devices of claim 3-7, it is characterised in that described electrostriction material includes piezoelectric ceramics.

9. a touch display panel, it is characterised in that include the arbitrary described haptic feedback devices of claim 1-8.

10. touch display panel according to claim 9, it is characterized in that, also include touch screen and display floater, described touch screen is arranged on the display side of described display floater, described deformation structure can being arranged on the side of described touch screen described display floater dorsad, described controller obtains, by described touch screen, the positional information that described user touches.

11. a touch display unit, it is characterised in that include the arbitrary described touch display panel of claim 9-10.