Data entry interfaces, such as keyboards or keypads, are typically used by a user for entering data into devices, such as mobile devices, e.g., mobile telephones, personal digital assistants, calculators, handheld computers, etc. Keypads for mobile devices are typically small due to the compact nature of mobile devices. As such, the individual keys of a keypad are located rather close together and have a rather small surface area, especially for keypads with 20 or more keys. This can make the keyboard difficult to operate in that a user's finger can depress more than one key at a time.
It is difficult to manufacture keys with such small surface areas in that it is difficult to form indicia on such keys that can still be readable by the user. Moreover, since all of the keys are about the same size and shape it is relatively easy to get the keys mixed up during assembly.
In the following detailed description of the present embodiments, reference is made to the accompanying drawings that form a part hereof, and in which are shown by way of illustration specific embodiments that may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice disclosed subject matter, and it is to be understood that other embodiments may be utilized and that process, electrical or mechanical changes may be made without departing from the scope of the claimed subject matter. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the claimed subject matter is defined only by the appended claims and equivalents thereof.
Although keypad 120 is shown to have 20 keys organized in 4 rows and 5 columns, keypad 120 may have any suitable number of keys organized in any suitable number of rows and columns. For example, keypad 120 may have 20 keys organized in 5 rows and 4 columns or 12 keys organized in 4 rows and 3 columns or 3 rows and 4 columns.
Two keys 210 respectively from successively adjacent columns 230 are combined to form one or more key pairs 240, e.g., side-by-side key pairs, as shown in
The respective keys 210 of each key pair 240 and each key pair 250 are physically connected. Each key pair may include a groove 260 that extends part of the way through a thickness of the respective key pair and interposed between the keys 210 of the key pairs. Grooves 260 cause the key pairs to have the appearance of two single stand-alone keys.
The respective keys 210 of each key pair share the plunger layer 310 and cap layer 320 of the respective key pair. In other words, each key pair has one continuous plunger layer 310 and one continuous cap layer 320 that are common to each key 210 of the key pair, as shown in
A stiffening layer, such as a stiffening framework 330, may underlie and may be in direct physical contact with the plunger layer 310.
Although plungers 312 are shown as being generally substantially centered within their respective keys 210 in
Key pad 120 is positioned over a circuit board 350, e.g., a printed circuit board, of mobile device 100, as shown in
When the key pair is positioned over a circuit board 350, plungers 312 may directly overlie and may be vertically aligned with domes 365, as shown in
Note that each single stand-alone key 212 has substantially the same cross-section as shown in
Each key 210 of a key pair or each stand-alone key 212 that is contained within a respective frame of framework 330 includes a portion of plunger layer 310 and a portion of the cap layer 320 that directly overlies the respective portion of plunger layer 310, as shown in
When a force F is applied, e.g., by a user's finger, to an upper surface of either a stand-alone key 212 or a key 210 of a key pair, portions of framework 330 are deflected in the direction of the force F toward circuit board 350, as shown in
The neutral position of a key 210 is also shown in
Note that each stand-alone key 212 responds to a force F applied thereto in substantially the same way, as shown at the left of
When a key 210 is actuated in response to the force F, the plunger 312 of that key 210 moves against the respective dome 365 causing the respective dome 365 to collapse into contact with circuit board 350, as shown in
Collapsing the dome 365 into contact with circuit board 350 may cause the dome 365 to complete a circuit of circuit board 350. For example, the collapsed dome 365 may close an otherwise open pair of contacts on circuit board 350. Completion of the circuit causes one of the functions indicated on the upper surface of the key to be performed. For example, the number or letter on the key 210 may be input, or the action indicated on the key 210 may be performed. Removing the force F causes the key and dome to return to their original positions, e.g., their neutral states.
Each stand-alone key 212 operates in substantially the same way as a key 210 when the force F is applied to the stand-alone key 212. That is, the plunger of the stand-alone key 212 moves against the respective dome 365, causing the respective dome 365 to collapse into contact with circuit board 350, as shown in
For one embodiment, height of each dome 365 is such that the length of the keystroke (e.g., about 0.3 millimeters) of a key 210 of a key pair is such that a user is unable to perceive that the key 210 is part of a key pair. A keystroke may be defined as the distance between when a key 210 is in its neutral position (as indicated by the dashed line in
Keypad 120 may include an option key (e.g. the Opt key in
Although the individual keys 210 of each key pair are physically connected, the individual keys 210 of each key pair can be moved independently of each other in response to forces independently applied to the respective keys 210 by a user. The independent movement of each key 210 can activate a function of key pad 120 specific to the respective key 210.
Stand-alone keys 212 can be moved independently of each other and the individual keys 210 of each key pair in response to a force applied to a key 212 by the user. The independent movement of each stand-alone key 212 can activate a function of key pad 120 specific to the respective key 212.
For one embodiment, left-right navigation of display 110 may be incorporated into a side-by-side key pair 240. For example, continuously depressing the left key of the side-by-side key pair 240 for at least a certain time may cause a cursor displayed on display 110 to move left, and continuously depressing the right key for at least the certain time may cause a cursor displayed on display 110 to move right.
Similarly, up-down navigation of display 110 may be incorporated into an over-under key pair 250. For example, continuously depressing the upper key of an over-under key pair 250 for at least a certain time may cause a cursor displayed on display 110 to move upward, and continuously depressing the lower key of the over-under key pair 250 for at least the certain time may cause a cursor displayed on display 110 to move downward.
Volume control may be incorporated into either a side-by-side key pair 240 or an over-under key pair 250. For example, continuously depressing the right key of a side-by-side key pair 240 or the upper key of an over-under key pair 250 for at least a certain time may cause the volume to increase, and continuously depressing the left key of a side-by-side key pair 240 or the lower key of an over-under key pair 250 for at least the certain time may cause a decrease in volume.
The key pairs disclosed herein act to simplify keypad fabrication in that the key pairs provide a larger surface area on which to dispose indicia as compared to a single stand-alone key. The larger surface area makes the keyboard easier to operate in that it is less likely that a user's finger will depress more than one key at a time. The key pairs reduce the number of individual keys and thus simplify assembly of the keypad by reducing the number of parts. The reduced number of keys also reduces the likelihood of incorrect assembly compared to when larger numbers of single stand-alone keys are used in that for a larger number of keys the keys are more likely to get mixed up, reducing yield.
Although specific embodiments have been illustrated and described herein it is manifestly intended that the scope of the claimed subject matter be limited only by the following claims and equivalents thereof.
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