The invention relates to a dynamic display keyboard. The invention further relates to a corresponding key for a dynamic display keyboard.
There is today a large demand on dynamic display keyboards in which the symbols of the keyboard may be dynamically changed such as for example one day to provide a set of Cyrillic characters and the next day a set of Chinese characters.
A problem of the existing dynamic display keyboards is, among other things, their lack of resemblance with traditional keyboards with respect to e.g. size, weight and tactile behaviour of the keys.
It is an object of the present invention to, among other things, solve the abovementioned problem. The abovementioned problem is solved by a dynamic display keyboard comprising a plurality of key elements, wherein each key element comprises a transmitting part configured for transmitting at least a part of light incident on the transmitting part. The dynamic display keyboard further comprises an elevated element for each key element, wherein each elevated element is configured for providing tactile feedback. The dynamic display keyboard may further comprise at least one spacer for each key element for fixedly connecting each key element to at least one respective elevated element. The dynamic display keyboard further comprises a display unit that may comprise a frame part and may comprise a moveable part for each key element. Each movable part may be movable in relation to the frame part. An outer part of each moveable part may be situated between a respective key element and the corresponding elevated element. The display unit may further be configured such that light from a respective outer part, which light propagates through a respective transmitting part, defines a visual value of the corresponding key element.
Thereby is achieved that the keyboard is dynamic and further is able to provide a tactile feedback in response to a user action directed towards a key of the keyboard. Further, the only power requiring element in the keyboard is the display unit. Further is provided a dynamic display keyboard that may be integrated into existing keyboard technology e.g. scissor-element keyboards.
Other embodiments and advantages are provided below in the detailed description, in the claims and in the drawings.
a illustrates an embodiment of a dynamic display keyboard.
b illustrates an embodiment of a circular cross-sectional form along the X-X axis of a dome element.
c illustrates an embodiment of a square cross-sectional form along the X-X axis of a dome element.
d) illustrates the display unit placed above the mat.
a) illustrates an embodiment of a key 1200 of a dynamic display keyboard.
b) illustrates an embodiment of
a) illustrates an embodiment of a dynamic display keyboard 100. The dynamic display keyboard comprises a plurality of key elements 101 e.g. a plurality of alpha-numeric keys. Each of the key elements 101 comprises a transmitting part 102 capable of transmitting at least a part of light incident on the transmitting part 102.
In an embodiment, the transmitting part 102 may be made of and/or may comprise a transparent polymer or of silica glass or the like i.e. a material having a high transmittance of the incident light. In an additional embodiment, the transmitting part 102 may be made of and/or may comprise a material having a high transmittance of incident light visible to a human being i.e. in the wavelength range from approximately 380 nm (violet light) to approximately 750 nm (red light).
The transmitting parts 102 may be positioned at the top of the key elements 101 as indicated in
The dynamic display keyboard 100 may further comprise a mat 105 made of and/or comprising an elastic and flexible material such as rubber. The mat 105 may comprise a plurality of elevated elements such as dome elements 106, 107, 109 capable of providing a tactile feedback. The dome elements 106, 107, 109 may be made in the same material as the mat 105. The mat 105 comprising the dome elements 106, 107, 109 may in one embodiment be cast in one piece. The dome elements 106, 107, 109 may be open in one end 118 facing the mat 105 and closed in the other end 117 facing the transmitting part 102. Further, the dome elements 106, 107, 109 may be hollow.
Each key element 101 is fixedly connected to at least one dome element 106 as disclosed below. As seen in
In a computer keyboard, for example, a SHIFT key may be fixedly connected to two dome elements, an alpha-numeric key may be fixedly connected to one dome element, and the spacebar may be fixedly connected to four dome elements.
The term fixedly connected is to be understood as the key element may be resting on the dome element and/or it may be glued or vulcanized to the dome element and/or welded to the dome element and/or cast with the dome element.
In an embodiment, the dome elements 106, 107, 109 provides control of the dimensions in which the key elements 101, 108 may move in. The dome elements 106, 107, 109 may in an embodiment restrict the direction in which the key elements 101, 108 may move. In an embodiment, the direction to which the key elements may move may be the direction 110 perpendicular to the rubber mat 105 or substantially perpendicular to the rubber mat 105 e.g. 90 degrees+/−5 degrees.
In order to have the dome element deform, an external force provided by a user pressing the associated key element, is required. The dome elements may be made of and/or may comprise a soft plastic or rubber or any other material capable of deforming along the direction of movement 110 when an external force having a component in the direction of movement 110 is applied to the key element 101. In an embodiment, the dome element 106 may be such as to require a threshold force in the direction of movement 110 before deforming thereby providing a tactile response to a user applying a force to the key element 101 and making the dome element able to sustain the weight of the key element 101 without any substantial deformation in the direction of movement 110 of the key element when an external force is not applied.
Thereby, the dome element 106, 107, 109 is able to provide a tactile feedback in response to a user action e.g. a user pressing the key element.
The key element 101 may be made of and/or may comprise a material harder than the dome element. For example, the key element 101 may be made of and/or may comprise melamine resin.
b) illustrates a circular cross-sectional view along the X-X axis of a dome element 106, 107, 109.
c) illustrates a square cross-sectional view along the X-X axis of a dome element 106, 107, 109.
The dynamic display keyboard 100 may further comprise at least one display unit 111. The display unit 111 is configured to provide light to the plurality of transmitting parts 102. The display unit 111 may comprise an LCD or OLED in which a pixel or a group of pixels 112 of the display are assigned to a key element 101. As seen in
As seen in
In an embodiment, the dynamic display keyboard 100 may additionally comprise a printed circuit board (PCB) 115 comprising a plurality of pads 119 for determining whether a key element 101, 108 has been pressed. The pads may in an embodiment be made of and/or may comprise carbon e.g. an electrically conducting carbon.
The PCB may be positioned below the display unit 111.
Each pad 119 comprises a first and a second pad part, and the first pad part is electrically isolated from the second pad part. When a key element 101 is depressed, a conductive element 120 passes through an opening left in the light generating layer 111 by the group of pixels 112 stamped out in the display unit 111 and is brought into contact with the first and second pad parts thereby short circuiting the first and second pad parts of at least one pad 119, thereby enabling detection of the depressed key element 101.
Further, passages or openings 113, such as holes, are included in the mat 105. The passages 113 are placed such as to enable parts of the display unit 111 to be passed through the mat 105.
In an embodiment, a processing unit 1001 may be communicatively coupled to the light generating layer 111 via a wireless and/or wired communication link 1002 such as Bluetooth or cable. The processing unit 1001 may determine which characters are to be displayed on which key elements 101 by providing a control signal to the respective group of pixels 112 under the key elements 102. In an embodiment, the processing device 1001 further comprises a power providing unit such as a connection to a power grid and/or a battery.
In an embodiment, any of the below-mentioned embodiments of
In an embodiment, the PCB circuit is communicatively coupled to the processing unit 1001 via a wireless and/or wired communication link such as Bluetooth or cable. The value of a detected depressed key element 101 may be transmitted from the PCB circuit to the processing unit 1001 for further processing.
In an embodiment as illustrated in
In embodiment, the thickness of the thin layer display unit 911 is in the range 0.05 mm to 0.5 mm such as 0.1 mm to 0.2 mm.
In embodiments, the thickness of the thin layer display unit 911 is less than 2 mm, such as less than 1 mm, such as less than 0.5 mm, such as less than 0.2 mm.
The thin layer display unit 911 comprises a stamped out part (movable part) 901, 902, 903 (defining respective light generating layers) for each of the plurality of key elements 101, 108, 117, which represents the plane of the thin layer display unit perpendicular to the direction 110 e.g. the plane of the keys in a computer keyboard. Each of the stamped out parts 901, 902, 903 constitutes individual display units contained in the thin layer display unit 911.
As is clearly illustrated in
Each movable part may be movable in relation to the frame part. Thus, a movable part may be moved during a movement of a respective key element.
As an alternative to stamping (or punching) out parts of the display unit, the display unit may be produced such that the plurality of movable parts and the frame are provided without punching (or stamping out) parts of the display unit, but by producing the display unit as a whole, e.g. by means of moulding the display unit.
As an alternative to the stamped (or punched) out parts, a cut or a break in the display unit may be provided along a line where material otherwise would have been removed. Thus, in embodiments, no parts of the display unit are removed during the generation of the movable parts.
An outer part 904 of the stamped out part (movable part) 901 is positioned between the transmitting part 102 and the dome element 107 of each of the key elements 101, 106, 109 as illustrated in
In an embodiment, each pixel of the outer part 304 of each of the stamped out parts is addressed via a data-bus integrated in the thin layer display unit.
In an embodiment of
The width 999 may enable flexibility in the group of pixels 112 of the thin flexible display unit 911 when the associated key element 101 is moving during a depression from an equilibrium state or a return to the equilibrium state (un-pressed key element).
The key 1100 comprises a scissor element 106. The scissor element 106 may comprise a closed top 1101 under which a rod 1102 may be attached by glue, vulcanization, welding or the like. The rod 1102 may be made of and/or may comprise a conductive material such as iron doped rubber or the like. The scissor element 106 may further comprise two X-formed structures which may be collapsible around a pivotal point 1103 like an opening scissor.
Further, the scissor element 106 may be fixedly connected to a key element 101 via spacers (not illustrated) placed at the corners of the top 1101. The spacers may be fixed to the key element 101 and to the top 1101 by glue, vulcanization, welding or the like. Thereby, the spacers create a gap between the top 1101 and the key element 101 in which gap, an outer part 904 of a stamped out part 901, 902, 903, may be placed. The outer part 904 is thus movable connected (not fixed) to the key element 101 or to the top 1101, but may glide on the surface of the top 1101 when the key element 101 is depressed. The outer part 904 is kept in place between the top 1101 and the key element 101 by its connection to the thin flexible layer display unit 911. Further, the spacers may additionally act as rails by which the outer part 904 may be kept in place in the lateral direction 1107.
When a force 1104 is applied to the key element 101 fixedly connected to the top 1101 via the spacers, the bottom part of the X-structures slides on a rail or track along the direction 1105 thereby reducing the height of the scissor element 106. At a point, the rod 1102 will come into physical contact with a pad arrangement 119 of the PCB 115, whereby electrical contact is made between the two pad parts and the key element 101 pertaining to the scissor element 106 may be detected as having been depressed.
The PCB 115 may be arranged in a mat-like structure as illustrated in
The embodiment 1100 may be used in a low profile type keyboard such as known from laptops and the like. A low profile type keyboard may be a keyboard where the individual keys comprise a part (key element) to be moved by a finger, which part is configured to travel less than e.g. 3 mm, such as less than 2 mm, during a keystroke by a user.
Further, as described above, the dynamic display keyboard 200 further comprises a mat 105 made of and/or comprising an elastic and flexible material such as rubber. The rubber mat 105 may comprise a plurality of elevated elements such as dome elements 201, 202 capable of providing a tactile feedback as described above.
The dome elements 201, 202 of
In an embodiment, the dynamic display keyboard 200 may comprise a thin flexible layer display unit 911.
A group of pixels 112 (i.e. e.g. contained in a movable part of the display unit) are positioned between the key element 101 comprising the transmitting part 102 and the closed dome element 205. Light emitted by the group of pixels 112 may pass the transmitting part 102. The group of pixels 112 may comprise one or more pixels in one or two directions i.e. a linear or planar arrangement of pixels may be comprised in the group of pixels 112.
The part of the display unit 904 comprising the group of pixels 112 may be placed against the key element 101 or against the top of the closed dome element 205 or it may be in no physical contact with the top of the closed dome element 205 or the key element 101 i.e. hovering in between the key element 101 and the dome element 205 by being supported by the rest of the stamped out part 901.
Further, passages 113, such as holes, are included in the mat 105. The passages 113 are placed such as to enable parts of the thin flexible layer display unit 911 to be passed through the mat 105.
In this embodiment, the rubber mat 105 further comprises fixators 205 to which the key elements 101 may be fixated e.g. by gluing, vulcanization, welding or the like. The horizontal distance between to opposing inner sides of the fixators 205 may correspond to size of the transparent part 102 in the respective dimensions of the plane containing the transparent part 102. The fixators 205 may be made of and/or may comprise a hard plastic or rubber material such as to provide a stable platform on which the key element 101 may be placed.
In an embodiment, the fixators 205 are able to conduct an electric current. For example, the hard plastic or rubber may be doped with a metallic powder such as iron or the like. Alternatively or additionally, the fixators 205 may contain an electric wire providing an electrically closed loop.
In an embodiment, the fixators 205 are cast during production of the mat 105.
In an embodiment, the dynamic display keyboard 100 may additionally comprise a printed circuit board (PCB) 115 comprising a plurality of pads 119 for determining whether a key element 101, 108 has been pressed.
The PCB may be positioned below the display unit 111 and below the elastic and flexible mat 105.
Each pad 119 comprises a first and a second pad part, and the first pad part is electrically isolated from the second pad part. When a key element 101 is depressed, a conductive element 120 passes through an opening left in the light generating layer 111 by the group of pixels 112 stamped out in the display unit 111 and is brought into contact with the first and second pad parts thereby short circuiting the first and second pad parts of at least one pad 119, thereby enabling detection of the depressed key element 101.
Further, passages or openings 113, such as holes, are included in the mat 105. The passages 113 are placed such as to enable parts of the display unit 111 to be passed through the mat 105.
In an embodiment, the display unit 111 may be placed above the mat 105. Thus, the mat 105 may be cast without the openings 113.
a) illustrates an embodiment of a key 1200 of a dynamic display keyboard. The key comprises a dome element 201 and pertaining key element 101 comprising a transparent part 102. The dome element 201 is cast e.g. in one piece and the fixator 205 may be cast in the same production step. The fixator 205 is solid in order to enable an outer part 904 of a stamped out part 901 of a display unit (not illustrated) to be placed on the fixator 205. The display unit (not illustrated) may be placed below the mat 105. A number of spacers 1201 (in this embodiment four spacers 1201 placed at each corner of the fixator 205; alternatively two spacers each running along the part 904 of the display positioned between the key element and the fixator 205) are fixedly connected to the fixator 305 by glue, vulcanization, welding or the like. On top of the spacers, the key element 101 is fixedly connected using glue, vulcanization or the like. Thereby, a volume exist between the key element 101 and the fixator 205 in which volume the outer part 904 of the stamped out part 901 of the display unit (not illustrated) may be positioned. An opening 113, such as a hole or the like, is contained between the dome element such that the stamped out part 901 may be guided through the opening 113 such that the outer part 904 of the stamped out part 901 may be placed in the volume (either against the fixator 205 or the key element 101 or floating in the air due to the connection to the stamped out part 901). Thereby, the outer part providing the alpha-numeric value of the key element 101 is able to move freely in the plane of the fixator 205 when the key element 101 is depressed.
b) illustrates an embodiment of
The layer 401 may comprise a collar/ridge 402. The collar/ridge 402 may be made of and/or may comprise an elastic and flexible material such as rubber. Additionally, the layer 401 may comprise a rigid part 404 made of and/or comprising a hard and non-flexible plastic.
Between the rigid part 404 and the mat 105 (in the direction 110), supporting elements 403 may be positioned i.e. between the dome elements 201 of the mat 105 (in the direction 405). The supporting elements 403 support the layer 401. The supporting elements 403 may be glued or vulcanized or welded to the rigid part 404 and the mat 105.
The key elements 101 comprises a transparent part 102 i.e. a transparent window. The key elements 101 may be glued or vulcanized or welded to the collar/ridge 402.
In an embodiment, the collar/ridge 402 is made of and/or comprises a transparent elastic and flexible material.
The dynamic display keyboard further comprises a group of pixels 112 associated with an outer part 904 of a stamped out part 901 of the display unit 901. The stamped part 901 is guided through a hole 113 in the mat 105 such that the outer part 904 may be positioned between the key element and the fixators 205.
In an embodiment, the dynamic display keyboard 400 comprises a PCB circuit 115 below the thin flexible layer display unit 911.
In an embodiment, the height from the top of a respective outer part 904 to the frame part of the thin flexible layer display unit 911 plane is in the range from about 2.0 mm to about 3.0 mm, i.e. e.g. from 2.0 mm+/−0.3 mm to 3.0 mm+/−0.3 mm.
In an embodiment, when a key element 101 is depressed, the electrically conductive fixators 205 passes through an opening 113 left in the light generating layer 111 by the group of pixels 112 stamped out in the display unit 111 and is brought into contact with the first and second pad parts of the PCB 115 thereby short circuiting the first and second pad parts of at least one pad 119, thereby enabling detection of the depressed key element 101 by the PCB 115. The detected depressed key value may be transmitted to the processing unit 1001 for further processing. 301 and 302 denotes depressed/flexed dome elements 201, 202 and 410 and 412 denotes depressed/flexed collar/ridge elements 402 and 411.
This embodiment, among other things, provides a keyboard with a layer 401 that is easily cleaned and which prevents dust and other things or fluids from falling in between the dome elements 201.
The device 700 may comprise a sliding mechanism such that the device may be in a closed state as indicated in
In an embodiment, the detachable part 602 and the thin flexible layer display unit 911 may be hinged together in order to enable the sliding according to
In one aspect, the above-described dynamic display keyboard may be used to e.g. provide different values to a key in a keyboard. One day, the keyboard may provide Latin alphabet key values and the next day Cyrillic alphabet key values. Alternatively or additionally, the dynamic display keyboard may ease use of special keys such as Alt Gr, CTRL, etc. When pressing one of these special keys, the dynamic display keyboard may only illuminate the keys and key values that can be reached in combination with the special key pressed down.
In an embodiment, the keyboard may be included in a computer system via a wired and/or wireless communication link such as an electric cable and/or a Bluetooth link. In this embodiment, the keyboard may comprise a short-range radio receiver and transmitter (e.g. a Bluetooth transmitter and receiver) and the computer system may comprise a similar short-range radio receiver and transmitter. Additionally or alternatively, the keyboard and the computer system may comprise a socket for an electric wire via which the computer system and the keyboard may be connected via an electric wire.
Although some embodiments have been described and illustrated in detail, the invention is not restricted to them, but may also be embodied in other ways within the scope of the subject matter defined in the following claims. In particular, it is to be understood that other embodiments may be utilised and structural and functional modifications may be made without departing from the scope of the present invention.
In device claims enumerating several means, several of these means can be embodied by one and the same item of hardware. The mere fact that certain measures are recited in mutually different dependent claims or described in different embodiments does not indicate that a combination of these measures cannot be used to advantage.
Throughout the description, terms such as “above” and “below” should be understood in a context where the keyboard is situated on a horizontal surface with the key elements facing upwards for operation by a user of the keyboard.
It should be emphasized that the term “comprises/comprising” when used in this specification is taken to specify the presence of stated features, integers, steps or components but does not preclude the presence or addition of one or more other features, integers, steps, components or groups thereof.
Items
Number | Date | Country | Kind |
---|---|---|---|
10158765.7 | Mar 2010 | EP | regional |
61341445 | Mar 2010 | US | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP11/55067 | 3/31/2011 | WO | 00 | 12/7/2012 |