1. Field of the Invention
The present invention relates to an input apparatus having at least one input key assigned a plurality of information items to be inputted, and to the input key.
2. Related Background Art
The portable terminals such as cell phones need to be compact enough to be carried by users. For this reason, where the portable terminals are provided with a keyboard, the number of keys in the keyboard is often much smaller than that in the so-called full keyboard.
In the case as described above, it is common practice to assign one key a plurality of symbols. A conventionally proposed method of inputting a plurality of symbols through one key is to detect a direction of a force exerted on the key and input an independent symbol by the direction. For example, Japanese Patent Application Laid-Open No. 2003-296001 discloses the following technology of detecting the direction of the push on the key, for substantializing this idea. This technology is such that switches and protruding portions according to push directions are provided inside the key, and with a push, a protruding portion turns on a switch according to a direction of the push, thereby detecting the direction of the push.
However, the above method requires a considerably careful operation to avoid actuation of the switch in the central direction (vertical direction) during a push in the forward, backward, left, or right direction, and there is thus still room for improvement in an aspect of operability.
The present invention has been accomplished in order to solve the above problem and an object of the present invention is to provide an input key and an input apparatus superior in operability.
In order to achieve the above object, an input key according to the present invention is an input key which is assigned a plurality of information items to be inputted, comprising: a key top which can incline relative to a support plate for supporting the input key; a key top supported portion provided on an opposite surface in the key top to the support plate and arranged to be pushed together with the key top; a key top supporting portion provided on the support plate, and arranged to come into contact with the key top supported portion during a push on the key top and to support the key top supported portion so as to permit the key top to incline in a state of the contact with the key top supported portion; at least one inclination detector provided in a direction assigned one of the information items to be inputted, on an opposite surface in the support plate to the key top or on the opposite surface in the key top to the support plate; push detecting means for detecting a push on the input key; and inclination direction detecting means for detecting an inclination direction of the key top when the push detecting means detects a push on the input key. Here the term “information items to be inputted” includes information generally assigned to each of input keys in the so-called full keyboard, e.g., information such as symbols, numbers, and marks, information of the linefeed code and control code, and so on.
A user of the input key according to the present invention pushes an input key corresponding to an information item to be inputted, while inclining a key top of the input key in a direction corresponding to the information item to be inputted. In the input key, first the push brings the key top supported portion into contact with the key top supporting portion to establish a supported state. Subsequently, the key top inclines into the direction in which the user inclines it, in the supported state (a stable state with the key top supporting portion and the key top supported portion serving as an axis). This causes an inclination detector corresponding to the direction of the inclination to come into contact with a surface opposed to the inclination detector (e.g., the support plate, or the opposite surface on the key top side (or the key top supported portion)).
Then the push detecting means detects the push on the input key. When the push is detected, the inclination direction detecting means detects the contact of the inclination detector with the surface on the opposite side. This makes it feasible to specify information corresponding to the direction of the inclination of the key top by the user (an information item to be inputted). The detection by the inclination direction detecting means (the detection of the contact of the inclination detector with the opposite surface) is implemented, for example, by the following method. Describing an example of the contact of the inclination detector with the support plate, an electrode to conduct electricity upon the contact of the inclination detector with the support plate is embedded in the support plate and the electric conduction is detected to detect the contact of the inclination detector with the opposite surface. In another configuration, a button or a switch or the like is provided at the contact part in the support plate in contact with the inclination detector and a push on the button or the switch or the like is detected. In still another configuration, a piezoelectric device or a strain gage or the like is provided at the contact part in the support plate in contact with the inclination detector and the push is detected by the piezoelectric device or the strain gage or the like. The foregoing “means for detecting the contact” such as the electrode to conduct electricity upon the contact, the button, the switch, the piezoelectric device, and the strain gage will be referred to hereinafter as “contact detecting means”.
As described above, the present invention enables stabler input based on the inclination of the key top around the axis on the key top supported portion and the key top supporting portion arranged to contact each other upon a push on the key top, thereby achieving better operability.
More specifically, the input key according to the present invention preferably has a configuration wherein the inclination detector is of such a protruding shape as to facilitate contact with the surface opposite to the surface where the inclination detector is provided, and wherein the inclination direction detecting means detects the contact of the inclination detector with the opposite surface to detect the inclination direction of the key top.
The input key according to the present invention also preferably has a configuration wherein the inclination detector is comprised of one or two out of: a key-top-side slope portion forming a part of the opposite surface in the key top to the support plate and formed so as to increase distance to the support plate from the interior side toward the exterior side; and a support-plate-side slope portion forming a part of the opposite surface in the support plate to the key top and formed so as to increase distance to the key top from the interior side toward the exterior side; and wherein the inclination direction detecting means detects contact of the inclination detector with the opposite surface to detect the inclination direction of the key top.
The input key according to the present invention also preferably has a configuration further comprising a key top periphery supporting portion formed of an elastically deformable material and arranged to support a peripheral portion in the key top so as to keep the distance substantially constant between the key top and the support plate.
The input key according to the present invention also preferably has a configuration wherein the inclination detector is provided on the opposite surface in the key top to the support plate, and wherein when the key top is inclined during a push on the key top, the key top supported portion comes into contact with the key top supporting portion to be supported by the key top supporting portion and the inclination detector comes into contact with the support plate.
The input key according to the present invention also preferably has a configuration wherein the inclination detector is provided on the opposite surface in the support plate to the key top, and wherein when the key top is inclined during a push on the key top, the key top supported portion comes into contact with the key top supporting portion to be supported by the key top supporting portion and the inclination detector comes into contact with the key-top-side opposite surface or with the key top supported portion.
More specifically, the input key according to the present invention preferably has a configuration wherein one of the key top supported portion and the key top supporting portion is of a convex shape and the other is of a concave shape. The above shapes enable securer support between the key top supported portion and the key top supporting portion, and the key top supported portion and the key top supporting portion function as an axis during the inclination of the key top, thereby enabling smoother inclination.
More specifically, the input key according to the present invention preferably has a configuration wherein contact detecting means for detecting contact is placed on both or either one of the inclination detector, and a surface with which the inclination detector comes into contact during an inclination of the key top, and wherein the inclination direction detecting means detects the contact of the inclination detector with the foregoing surface by the contact detecting means to detect the inclination direction of the key top. In particular, a button, a switch, a piezoelectric device, a strain gage, or the like may be placed on both or one of the inclination detector, and the surface to contact the inclination detector; or the both surfaces may be provided with electrodes to conduct electricity upon the contact. The piezoelectric device as an example of the contact detecting means is a device that generates a voltage upon occurrence of stress and is able to detect a pressure due to a push of the inclination detector. In the “arrangement” of the piezoelectric device, the piezoelectric device may be attached onto the both or one of the inclination detector and the surface to contact it or may be embedded in the both or one of the inclination detector and the surface to contact it.
The input key according to the present invention also preferably has a configuration wherein the support plate is formed of an elastically deformable material. Namely, when the user pushes the input key, the key top supported portion pushes the key top supporting portion and the pertinent part of the support plate gets dented by the pressure of the push to elastically deform the support plate into a concave shape. This causes the peripheral part of the key top supporting portion in the support plate (i.e., the part where the inclination detector is placed or the part where the inclination detector contacts the support plate) to relatively bulge, thereby decreasing the clearance between the inclination detector and the surface to contact the inclination detector. This results in decreasing the inclination amount into the direction corresponding to the information item to be inputted by the user, which makes the input of information easier.
The input key according to the present invention also preferably has a configuration wherein one portion or both portions in at least one combination out of combinations of portions to come into contact with each other inside the input key during a push on the input key are of an embossed structure. The embossed structure is a sheetlike structure bulging in the center. When a force over a given level is applied to the bulging portion, the central bulging portion collapses at a stretch to get dented to the other side. When the force over the given level is removed, the central bulging portion dented to the other side bulges (or recovers). Once the bulging portion bulges to a certain shape, it returns into the original bulging state at a breath. The embossed structure is formed of an embossed sheet or the like made of soft vinyl or the like.
As the user pushes the input key, the input key according to the present invention is subject to a reaction force from the embossed sheet before the force of the push reaches the aforementioned given level. However, once the user applies the force over the given level, the embossed sheet collapses at a stretch to be dented, so as to decrease the reaction at a breath. This permits the user to sense the decrease of the reaction at a fingertip during the push on the input key with a user's finger. As the user lifts the finger from the input key, the part of the embossed structure gradually returns from the dented state of the central bulging portion to the original shape to elevate the input key. When it returns up to a certain shape, the central bulging portion suddenly generates a strong restoring force to quickly increase the force to lift the input key.
As described above, the present invention permits the user of the input key to have a touch of a push on the key top, so called a “click feel”, and thereby obtain a light keying feel.
In order to achieve the above object, an input apparatus according to the present invention is an input apparatus for input of information through at least one input key assigned a plurality of information items to be inputted, comprising: (1) an input key comprising: (1a) a key top which can incline relative to a support plate for supporting the input key; (1b) a key top supported portion provided on an opposite surface in the key top to the support plate and arranged to be pushed together with the key top; (1c) a key top supporting portion provided on the support plate, and arranged to come into contact with the key top supported portion during a push on the key top and to support the key top supported portion so as to permit the key top to incline in a state of the contact with the key top supported portion; and (1d) at least one inclination detector provided in a direction assigned one of the information items to be inputted, on an opposite surface in the support plate to the key top or on the opposite surface in the key top to the support plate; (2) assignment information holding means for holding assignment information of each of the information items to be inputted, according to an inclination direction of the key top of the input key; (3) push detecting means for detecting a push on the input key; (4) inclination direction detecting means for detecting an inclination direction of the key top when the push detecting means detects a push on the input key; and (5) information determining means for determining an information item to be inputted, based on the inclination direction detected by the inclination direction detecting means and the information held in the assignment information holding means and fed according to the inclination direction.
Processing executed in the input apparatus according to the present invention will be described below. A user of the input apparatus pushes an input key corresponding to an information item to be inputted, while inclining the key top in a direction corresponding to the information item to be inputted. In the input key, first, the push brings the key top supported portion into contact with the key top supporting portion to establish a supported state. Subsequently, in this supported state (a stable state with the key top supporting portion and the key top supported portion serving as an axis), the key top inclines into the direction in which the user inclines the key top. This causes an inclination detector corresponding to the direction of the inclination to come into contact with a surface on the side opposite the inclination detector (e.g., the support plate, or the opposite surface on the key top side (or the key top supported portion)).
Then the push detecting means detects the push on the input key. When the push is detected, the inclination direction detecting means detects the contact of the inclination detector with the surface on the opposite side. Subsequently, the information determining means determines the information item to be inputted, based on the detected inclination direction and the information held in the assignment information holding means. This makes it feasible to specify information corresponding to the direction of the inclination of the key top by the user (an information item to be inputted).
According to the present invention, as described above, the key top is inclined about the axis on the key top supported portion and the key top supporting portion in contact with each other, so as to enable stabler input and achieve better operability.
In the input apparatus according to the present invention, preferably, one of the key top supported portion and the key top supporting portion is of a convex shape and the other is of a concave shape. The input apparatus according to the present invention also preferably has a configuration wherein contact detecting means for detecting contact is placed on both or either one of the inclination detector, and a surface with which the inclination detector comes into contact during an inclination of the key top, and wherein the inclination direction detecting means detects the contact of the inclination detector with the foregoing surface by the contact detecting means to detect the inclination direction of the key top. In particular, a button, a switch, a piezoelectric device, a strain gage, or the like may be placed on both or one of the inclination detector, and the surface to contact the inclination detector; or the both surfaces may be provided with electrodes to conduct electricity upon the contact. In the input apparatus according to the present invention, the support plate is preferably formed of an elastically deformable material.
Furthermore, the input apparatus according to the present invention preferably has a configuration wherein one portion or both portions in at least one combination out of combinations of portions to come into contact with each other inside the input key during a push on the input key are of an embossed structure. This configuration permits the user of the input key to have a touch of a push on the key top, so called a “click feel”, and thereby to obtain a light keying feel.
Incidentally, in a desired configuration of the input apparatus according to the present invention, the input apparatus further comprises controlling means for, during a push operation on an input key, outputting assignment information of a plurality of input information elements to the input key at a time of the operation, to an external display device and for making the display device highlight information of an input candidate corresponding to the push operation at the time, out of the plurality of input information elements.
This achieves the following three effects. Namely, (1) in a case where the assignment of the plurality of input information elements to the input key is changed according to frequencies of use or the like, the user can check the up-to-date assignment information on the external display device during a push operation on the input key. (2) For example, in a case where the input mode is switched from an input mode of Japanese hiragana writing symbols to an alphabet input mode, it is feasible to feed back to the user the assignment information of input information about the input mode after the switch, which cannot be readily displayed by only the display on the key top. Furthermore, (3) the user can also check the information as an input candidate corresponding to a push operation at the time of the operation (information selected at the time). The feedback function of up-to-date assignment information as described above can dramatically improve easiness and certainty of user operation.
The present invention enables stabler input and achieves better operability, based on the configuration of inclining the key top around the axis on the key top supported portion and the key top supporting portion in contact with each other during a push on the key top.
Various embodiments of the present invention will be described below with reference to the drawings. The following description will concern the first to fourth embodiments in configurations wherein inclination detectors of an input key according to the present invention are provided in a protruding shape on a support plate (i.e., on an opposite surface to a key top), the fifth to seventh embodiments in configurations wherein inclination detectors of an input key according to the present invention are provided in a protruding shape on a key top (i.e., on an opposite surface to a support plate), and the eighth embodiment in a configuration wherein inclination detectors of an input key according to the present invention constitute a part of an opposite surface in a key top to a support plate and are comprised of a key-top-side slope portion formed so as to increase the distance to the support plate from the interior side toward the exterior side, which will be described below in order.
Each input key 10 is assigned at least one symbol according to a direction of an inclination of a key top. In the description hereinafter, the hiragana writing symbols being one of the Japanese symbol formats will be used as an example of symbols to be inputted through the input keys 10. The Japanese hiragana writing symbols can be classified into a plurality of subgroups, and each subgroup consists of five symbols. These subgroups include the “ line” group consisting of five symbols () corresponding to five basic vowels, the “ line” group consisting of five symbols () corresponding to the foregoing five vowels coupled with a specific consonant “K”, the “ line” group consisting of five symbols () corresponding to the foregoing five vowels coupled with a specific consonant “S”, the “ line” group consisting of five symbols () corresponding to the foregoing five vowels coupled with a specific consonant “T”, and so on.
For example, the input key 10a is assigned a symbol group of the “ line group” according to directions of force as follows: “” in “up”; “” in “right”; “” in “down”; “” in “left”; “” in “center”. In addition, as shown in
The “directions” in the present embodiment will be described below with reference to
When a user of the input apparatus 200 enters a symbol, the user pushes an input key 10. Namely, where the user enters a symbol in the “ line group”, the user exerts a force on the key top 220 of the input key 10a to push it. The user can specify a symbol by pushing the key top with an inclination in one direction of “up”, “down”, “left”, or “right” or by pushing the key top in the “center” direction without inclination in any direction when exerting the force on the key top 220 of the input key 10a.
The assignment information holder 34 has a symbol conversion table as shown in
The push detector 36 detects a push on an input key 10 (the details of the detection method will be described later). The inclination direction detector 38 has a decision table shown in
As shown in
The key top 220 is a portion to which force is applied during a push on the input key 10, and is made of a material with some hardness, for example, such as hard plastic or metal, in order to enhance sensation of a push on the input key. The key skirt 230 is connected perpendicularly to the support plate 60 and holds the key top 220 with a constant space from the support plate 60 in a state without force on the key top 220. The key skirt 230 is made of an elastically deformable material, e.g., synthetic rubber, soft plastic, soft vinyl, or the like. As shown in
The key top supported portion 20 is of a protruding shape and is provided in the center on an opposite surface in the key top 220 to the support plate 60. The distal end of the key top supported portion 20 is of a semispherical convex shape and an electrode 21 is attached to that portion. The electrode 21 is made of a uniform conductor such as a metal piece. The key top supporting portion 30 is provided on the support plate 60 so as to rise from the other part of the support plate 60 (as being integral with the support plate 60), and is located with a space to the opposed part of the key top supported portion 20. When the key top 220 is pushed, the key top supporting portion 30 comes into contact with the key top supported portion 20. The contact part of the key top supporting portion 30 is of such a semispherical concave shape as to be able to support the convex part at the distal end of the key top supported portion 20. As shown in
The inclination detectors 54 are provided in the respective directions of up, down, left, and right around the key top supporting portion 30 on the support plate 60 and are arranged to further rise from the key top supporting portion 30. The inclination detectors 54 are of an elongated convex shape as shown in
The detection of the contact may also be implemented by any other method, e.g., a method of detecting the contact by a button, a switch, or the like set in the contact part, instead of the method of attaching the electrodes to the contact parts as described above.
The processing executed in the input apparatus 200 according to the present embodiment will be described below with reference to the flowchart of
When the user pushes an input key 10, the processing is started. The user pushes an input key 10 assigned a symbol to be inputted, while exerting a force so as to incline the key top 220 in a direction corresponding to the symbol to be inputted. For example, when the user desires to enter a symbol of “”, the user pushes the input key 10a assigned “”, while applying a force so as to incline the key top 220 in the right direction corresponding to “” as shown in
With the push, as shown in
Subsequently, the inclination direction detector 38 detects an inclination of the key top 220 as shown in
Subsequently, the push detector 36 detects an end of the push on the input key 10. The detection of the push end on the input key 10 is implemented by determining whether a duration to of a non-conducting state in which the electrode 21 attached to the key top supported portion 20 stays away from the electrode 31 attached to the key top supporting portion 30, exceeds a given value T0 (>0) (S14). When the push on the input key 10 is not finished, the processes of S12 to S14 are continuously performed. The determination on the duration of the non-conducting state is preferably carried out at very short time intervals, e.g., on the millisecond time scale.
When the push on the input key 10 is finished, the inclination direction detector 38 determines an inclination direction of the key top 220 in a manner as described below, from values tA to tE of the continuation durations of the inclination directions obtained as described above, based on the decision table (S15).
First, a decision on a push in the center direction (a push in a state in which the key top 220 does not incline in either direction) is made as follows. Values of rAB=tB/tA and others are derived from the duration tA of the push in the center direction and the duration tB of the inclination in the left direction and others (rXY hereinafter refers to tY/tX (X, Y=any two of A to E). Using these values, it is determined that the push in the center direction was made, if the following conditions are satisfied, as in the decision table shown in
Next, a decision on an inclination in one direction of the key top 220 during a push on the input key 10 is made as follows. A case of the inclination in the right direction will be described as an example. Just as in the above case, it is determined that the key top was inclined in the right direction, if the following conditions are satisfied, as in the decision table shown in
Subsequently, the symbol determiner 40 determines a symbol to be inputted, based on the symbol conversion table as shown in
Subsequently, the symbol determiner 40 outputs the symbol thus determined (S17).
As described above, the input apparatus 200 of the present embodiment enables stabler input based on the inclination of the key top 220 around the axis on the key top supported portion 20 in the input key 10. This makes it feasible to substantialize the input apparatus 200 superior in terms of operability. The key top 220 can be made in simpler structure, without need for providing the key top 220 with a plurality of projections, so that it becomes feasible to facilitate the production of input apparatus 200 and to decrease the cost of production.
In the present embodiment, as shown in
In the present embodiment, as shown in
In the present embodiment, as shown in
In the present embodiment the push detector 36 and the inclination direction detector 38 are constructed separately from the input key 10, but they may be constructed integrally with the input key 10 as shown in
The above system adopts the key input based on one symbol per push, but it is also possible to adopt continuous input of symbols based on continuation of a push state on the input key 10 as described below.
In the above-stated system, the inclination direction of the key top 220 was determined when the push on the input key 10 was finished, that is, when the duration to of the non-conducting state exceeded the constant value T0 (>0). Then the inclination direction is also determined if the following condition is satisfied.
As the inclination direction is also determined where the above conditions are met, the inclination direction of the key top 220 is determined during continuation of the push state, at appropriate intervals during the continuation, thus enabling the continuous input on the key.
Incidentally, the above embodiment showed the input example of the Japanese hiragana writing symbols with
For example, as shown in
As shown in
The symbol assignment to the twelve keys 161 in the symbol input key arrangement part 160B is, for example in the case of the hiragana writing symbols, that as shown in
As shown in the assignment to the keys K10, K11 in the table of
Furthermore, the special symbols among the hiragana writing symbols include an example of display of symbols in size smaller than usual (e.g., “”, “”, etc.), an example of display of voiced consonants (e.g., “”, “”, etc.), and an example of display of p-sounds (e.g., “”, “”, etc.). In addition, the hiragana writing symbols are often converted into katakana small symbols or katakana large symbols. Therefore, as shown in the assignment to the key K12 in the table of
The above described the key assignment about the input of the Japanese hiragana writing symbols, but the present invention, which facilitates the input operation by assigning a plurality of symbols, marks, or functions to one key as shown in
First, an example of application of the present invention to input of English symbols will be described. The English symbols (alphabet) include twenty six symbols in total, and are not grouped into symbol groups each consisting of five symbols, different from the Japanese hiragana writing symbols. Thus a conceivable method is to assign five symbols to each key in order from the top of the alphabet (A, B, C, . . . ), as shown in
This enables one to input the symbol types equivalent to those through the full keyboard by one operation (a movement of a finger). Namely, the function equivalent to that of the full keyboard can be substantialized by the smaller number of input keys, and the input of symbols can be implemented by the reduced number of input operations, thus dramatically improving the efficiency of input operation.
A switchover among four symbol types of half-width English lower-case symbols, full-width English lower-case symbols, half-width English upper-case symbols, and full-width English upper-case symbols can be implemented by manipulating the F key 162 in
The assignment of the alphabet and marks to each of the keys (K1–K12) in
Next, an example of application of the present invention to input of the German symbols will be described. For input of the German symbols, it is necessary to input peculiar symbols such as symbols with the Umlaut mark (e.g., Ä, Ö, Ü, etc.) and β (Eszett), in addition to the input of the same alphabet as in English.
Thus the peculiar symbols as described above can replace the mark-assigned portions in the assignment table of
Next, an example of application of the present invention to input of the French symbols will be described. In order to input the French symbols, it is necessary to input the peculiar symbols as described below, in addition to the input of the same alphabet as in English. Namely, the peculiar symbols are é (accent aigu), à, è, ù (accent grave), â, î, û, ê, ô (accent circonflexe), ï, ü, ë (tréma), c (cédille), œ (o e composé), and so on.
Thus the peculiar symbols as described above can replace the mark-assigned portions in the assignment table of
Next, an example of application of the present invention to input of the Chinese symbols will be described. A common Chinese symbol input method is the pin-yin input system of inputting an alphabet sequence (pin-yin) equivalent to the reading (pronunciation) of a symbol as an input object. This pin-yin input system is classified under two input methods of complete pin input and bi-pin input.
The complete pin input uses the English keyboard as it is, and pin-yin is inputted in each symbol unit according to the alphabetical notation on the keyboard. For example, where Chinese “” corresponding to “ (sunny today)” is inputted, an alphabet sequence “JIN” corresponding to the reading (pronunciation) of “”, an alphabet sequence “TIAN” corresponding to the reading (pronunciation) of “”, and an alphabet sequence “QING” corresponding to the reading (pronunciation) of “” are inputted in order according to the alphabet notation on the English keyboard. Therefore, the key assignment as shown in
On the other hand, the bi-pin input is a way of inputting each symbol by separate use of Chinese (head consonant) and (subsequent vowel component). Here the “” means a consonant at the head of a syllable, and “” means a portion except for the head consonant in the syllable, the “” always containing a vowel. In the bi-pin input, symbols are inputted by switching in an order of (consonant)→ (vowel component)→ (consonant)→ (vowel component). Namely, this input method involves a device of reducing the number of typing operations on the keyboard by the separate use of and , and, once one learns the keyboard arrangement of the bi-pin input, he or she can input symbols by the smaller number of input operations than by the aforementioned complete pin input, so as to realize efficient symbol input.
The bi-pin input of this type requires two key assignments, (head consonant) key assignment for input of and (subsequent vowel component) key assignment for input of . The present invention can be applied to these key assignment and key assignment. For example,
In the bi-pin input, symbols are inputted by switching in the order of consonant→vowel component→consonant→vowel component as described above, and the key assignment is arranged to become the consonant key assignment of
In the bi-pin input, as described above, the consonant and vowel component key assignments as shown in
In the Chinese input, the marks (e.g., !, ?, etc.) other than the symbols are also often inputted. It is thus desirable to assign the various types of marks to the remaining portions in the key assignments of
Lastly, an example of application of the present invention to input of the Korean symbols will be described. Each Korean symbol (hangul symbol) is composed of a combination of a consonant with a vowel. Therefore, for symbol input, it is necessary to input a consonant-indicating part and a vowel-indicating part for each symbol. There are nineteen consonants and twenty one vowels, and forty portions indicating the total of these forty sounds are assigned to keys. An example of this assignment is presented in
Since the keys can be assigned the forty portions indicating the respective sounds, the forty sounds in total including the nineteen consonants and twenty one vowels, as described above, it becomes feasible to input the symbol types equivalent to those through the full keyboard by one operation (a movement of a finger). Namely, the function equivalent to that of the full keyboard can be substantialized by the smaller number of input keys, and the symbol input can be implemented by the reduced number of input operations, thereby dramatically improving the efficiency of input operation.
In the Korean input, the marks (e.g., !, ?, etc.) other than the symbols are also often inputted. It is thus desirable to assign the various types of marks to the remaining keys (keys K9–Kl2) in the key assignment of
As described above, the present invention is applicable to input of symbols in various languages, and achieves the excellent effects of substantializing the function equivalent to that of the full keyboard by the smaller number of input keys and enabling the symbol input by the reduced number of input operations, thereby dramatically improving the efficiency of input operation.
As shown in
As shown in
When the user pushes the input key 10, the key top is subject to reaction from the embossed structure portion 131a of the key top supporting portion 30 before the force of the push reaches a given level. Once the force applied exceeds the given level, the embossed structure portion 131a collapses at a stretch to become dented, so as to decrease the reaction at a breath. When the user pushes the input key 10 with a finger, the user can sense the decrease of the reaction at a fingertip. As the user lifts the finger from the input key 10, the embossed structure portion 131a gradually returns from the dented state of the central bulging portion to the original state, to elevate the input key 10. When the embossed structure portion returns to a certain shape, the central bulging portion suddenly generates a strong restoring force to quickly increase the force to lift the input key 10. In the dented state of the embossed structure portion 131a, the line 32a and the line 32b are in the conducting state through the electrodes as described above to detect a push on the input key 10. When the push force is eliminated, the central bulging portion of the embossed structure portion 131a recovers, and a non-conducting state is established, whereby an end of the push is detected.
In the dented state of the embossed structure portion 131a during a push on the input key 10, the key top supported portion 20 is supported by the embossed structure portion 131a, and thus the inclination of the key top 220 is made in a stable state in which the key top supported portion 20 in the supported state functions as a fulcrum.
The detection of the inclination of the key top 220 is also carried out in a manner similar to the detection of the push by the structure of the inclination detectors 54.
As described above, the input apparatus 200 of the present embodiment enables stabler input, and permits the user to have a touch of a push and inclination of the key top 220, so called a “click feel”. There is no need for provision of electrodes or the like on the key top 220, which can further simplify the structure of the key top 220.
In the present embodiment, as shown in
In the present embodiment, as shown in
As shown in
The key top supporting portion 30 is provided so as to rise from the other part of the support plate 60, on the support plate 60 (as being integral with the support plate 60), and is located with a clearance to the opposed portion of the key top supported portion 20. When the key top 220 is pushed, the key top supporting portion 30 comes into contact with the key top supported portion 20. The contact part of the key top supporting portion 30 is of a semispherical concave shape so as to be able to support the convex part at the tip of the key top supported portion 20.
The inclination detectors 54 are provided in the respective directions of up, down, left, and right around the key top supporting portion 30 on the support plate 60 and are arranged to further rise from the key top supporting portion 30.
Pressure detecting sheets 95, 96 are attached to the concave part of the key top supporting portion 30 and to the distal ends of inclination detectors 54, respectively. The pressure detecting sheets 95, 96 have a plurality of piezoelectric devices embedded therein, and are able to detect pressure of contact when the key top 220 is pushed and inclined to bring the key top supported portion 20 or the key top 220 into contact with the key top supporting portion 30 or with the inclination detector 54. This enables detection of the push and inclination of the key top 220. The support plate 60 itself is made of an elastically deformable material.
When the user pushes the key top 220, the key top supported portion 20 comes into contact with the pressure detecting sheet 95 to push the pressure detecting sheet 95. This push generates a voltage in a piezoelectric device in the pushed part, buried in the pressure detecting sheet 95, and the push is detected by sensing the voltage.
Since the support plate 60 is made of an elastically deformable material, it deforms so as to become dented in the pushed part as shown in
When the key top 220 is inclined to bring the key top 220 into contact with an inclination detector 54, the inclination can be detected in a manner similar to the above by the pressure detecting sheet 96.
As described above, the input apparatus 200 of the present embodiment enables stabler input in the simpler structure. The inclination of the key top 220 for information input becomes easier.
As shown in
As described in the first embodiment, the inclination detectors 54 are provided in the respective directions of up, down, left, and right around the key top supporting portion 30 on the support plate 60 and are able to detect an inclination of the key top 220. It is assumed herein that the relation of d1<d2 is satisfied by the distance d1 between the key top supported portion 20 and the key top supporting portion 30 and the distance d2 between the inclination detectors 54 and the key top 220 in a state in which no force is applied to the key top 220. This is for assuring establishment of a state in which the key top supported portion 20 comes into contact only with the key top supporting portion 30 when a force vertical to the key top 220 is exerted, and is also for assuring establishment of a state in which the key top supported portion 20 is always supported by the key top supporting portion 30 when an inclination detector 54 is in contact with the key top 220. Namely, this is for assuring establishment of a state in which a clearance is secured for a structure wherein the key top supported portion 20 comes into contact only with the key top supporting portion 30 and an inclination detector 54 is not in contact with the opposite surface when a force vertical to the key top 220 is exerted, and a push vertical to the key top 220 can be achieved surely, and is also for assuring establishment of a state in which the key top supported portion 20 supported on the key top supporting portion 30 is made to function as a fulcrum of inclination during the inclination of the key top 220.
As described above, the input apparatus 200 of the present embodiment enables stabler input, without providing the key top 220 with the protruding portion.
In the present embodiment, in order to achieve easier support of the key top supported portion 20 by the key top supporting portion 30, a guard portion 120 may be provided around the concave depression of the key top supported portion 20 as shown in
In the present embodiment, it is also possible to adopt a structure using a piston 180 as shown in
The fifth to seventh embodiments hereinafter will successively describe configurations wherein the inclination detectors of the input key according to the present invention are provided in protruding shape on the key top (i.e., on the opposite surface to the support plate). The configuration of input apparatus 200 in the fifth embodiment is much the same as that of the input apparatus 200 in the first embodiment. Namely, the exterior configuration of input apparatus 200 is the aforementioned configuration of
The key top 220 is a part on which force is exerted during a push on the input key 10 and is made of a material with some hardness, e.g., hard plastic, metal, or the like, in order to enhance the sensation of the push on the key. The key skirt 230 is connected vertically to the support plate 60 and holds the key top 220 with a certain space from the support plate 60 in a state in which no force is exerted on the key top 220. The key skirt 230 is made of an elastically deformable material, e.g., synthetic rubber, soft plastic, soft vinyl, or the like. As shown in
The key top supported portion 20 is provided in the center on the opposite surface in the key top 220 to the support plate 60. The distal end of the key top supported portion 20 is of a semispherical convex shape and an electrode 21 is attached to that part. The electrode 21 is made of a uniform conductor such as a metal piece. The key top supporting portion 30 is provided on the support plate 60 so as to rise from the other part of the support plate 60 (as being integral with the support plate 60) and is located with a clearance to the opposed part of the key top supported portion 20. When the key top 220 is pushed, the key top supporting portion 30 comes into contact with the key top supported portion 20. The contact part of the key top supporting portion 30 is of a semispherical concave shape so as to be able to support the convex part at the tip of the key top supported portion 20. As shown in
The inclination detectors 50 are provided in the respective directions of up, down, left, and right on the opposite surface in the key top 220 to the support plate 60. The distal end of the inclination detectors 50 is of a semispherical convex shape and an electrode 51 is attached to that part of each detector as in the case of the key top supported portion 20.
The detection of the contact may be implemented by any other method, e.g., a method of setting a button, a switch, or the like in the contact part and detecting the contact thereby, instead of the method of attaching the electrodes to the respective contact portions as described above.
The processing executed in the input apparatus 200 of the present embodiment will be described below with reference to the flowchart of
When the user pushes the input key 10, the processing is started. The user pushes an input key 10 assigned a symbol to be inputted, while exerting a force on the key top 220 so as to incline it in a direction corresponding to the symbol to be inputted. For example, where the user desires to enter a symbol of “”, the user pushes the input key 10a assigned “”, while exerting the force so as to incline the key top 220 in the right direction corresponding to “” as shown in
The push establishes contact between the electrode 21 attached to the key top supported portion 20 and the electrode 31 attached to the key top supporting portion 30, as shown in
Subsequently, the inclination direction detector 38 detects an inclination of the key top 220 as shown in
Subsequently, the push detector 36 detects an end of the push on the input key 10. The detection of the push end on the input key 10 is carried out by determining whether a duration t0 of a non-conducting state after separation between the electrode 21 attached to the key top supported portion 20 and the electrode 31 attached to the key top supporting portion 30 exceeds a given value T0 (>0) (S14). When the push on the input key 10 is not finished, the processes of S12 to S14 are continuously carried out. The determination on the duration of the non-conducting state is preferably carried out at very short time intervals, e.g., on the millisecond time scale.
When the push on the input key 10 is finished, the inclination direction detector 38 determines the inclination direction of the key top 220 as described below, from the values tA to tE of the durations in the inclination directions determined as described above, based on the decision table (S15).
First, a decision on a push in the center direction (a push in a state in which the key top 220 does not incline in either direction) is made as follows. Values of rAB=tB/tA and others are derived from the duration tA of the push in the center direction and the duration tB of the inclination in the left direction and others (rXY hereinafter refers to tY/tX (X, Y=any two of A to E). Using these values, it is determined that the push in the center direction was made, if the following conditions are satisfied, as in the decision table shown in
Next, a decision on an inclination in one direction of the key top 220 during a push on the input key 10 is made as follows. A case of the inclination in the right direction will be described as an example. Just as in the above case, it is determined that the key top was inclined in the right direction, if the following conditions are satisfied, as in the decision table shown in
Subsequently, the symbol determiner 40 determines a symbol to be inputted, based on the symbol conversion table as shown in
Subsequently, the symbol determiner 40 outputs the symbol thus determined (S17).
As described above, the input apparatus 200 of the present embodiment enables stabler input based on the inclination of the key top 220 around the axis on the key top supported portion 20 in the input key 10. This makes it feasible to substantialize the input apparatus 200 superior in terms of operability.
In the present embodiment, as shown in the vertical cross section of the input key of
In the present embodiment, as shown in
In the present embodiment, as shown in
In the present embodiment, as shown in
The above configuration permits the user to have a “click feel” from the instantaneous dent and strong restoring force of the embossed structure portion 90 via the piston 80, 82.
Furthermore, as shown in
In the present embodiment the push detector 36 and the inclination direction detector 38 are constructed separately from the input key 10, but they may be constructed integrally with the input key 10 as shown in
The above system adopts the key input based on one symbol per push, but it is also possible to adopt continuous input of symbols based on continuation of a push state on the input key 10 as described below.
In the above-stated system, the inclination direction of the key top 220 was determined when the push on the input key 10 was finished, that is, when the duration t0 of the non-conducting state exceeded the constant value T0 (>0). Here the inclination direction is also determined if the following condition is satisfied.
As the inclination direction is also determined where the above conditions are met, the inclination direction of the key top 220 is determined in continuation of the push state, at appropriate intervals during the continuation, thus enabling the continuous input on the key.
As shown in
As shown in
When the user pushes the input key 10, the key top is subject to reaction from the embossed structure portion 131a of the key top supporting portion 30 before the force of the push reaches a given level. Once the force applied exceeds the given level, the embossed structure portion 131a collapses at a stretch to become dented, so as to decrease the reaction at a breath. When the user pushes the input key 10 with a finger, the user can sense the decrease of the reaction at a fingertip. As the user lifts the finger from the input key 10, the embossed structure portion 131a gradually returns from the dented state of the central bulging portion to the original state to elevate the input key 10. When the embossed structure portion returns to a certain shape, the central bulging portion suddenly generates a strong restoring force to quickly increase the force to lift the input key 10. In the dented state of the embossed structure portion 131a, the line 32a and the line 32b are in the conducting state through the electrodes as described above to detect a push on the input key 10. When the central bulging portion of the embossed structure portion 131a recovers without force of the push, a non-conducting state is established, whereby an end of the push is detected.
In the dented state of the embossed structure portion 131a during a push on the input key 10, the key top supported portion 20 is supported by the embossed structure portion 131a, and thus the inclination of the key top 220 is made in a stable state in which the key top supported portion 20 in the supported state functions as a fulcrum.
The detection of inclination of the key top 220 is also carried out in a manner similar to the detection of the push, by the structure of the inclination detectors 50, and the portions of the support plate 60 to come into contact with the inclination detectors 50.
As described above, the input apparatus 200 of the present embodiment enables stabler input and permits the user to have a touch of a push and inclination of the key top 220, so called a “click feel”.
As shown in
As shown in
As shown in
As shown in
When the user pushes the key top 220, the key top supported portion 20 comes into contact with the pressure detecting sheet 95 to push the pressure detecting sheet 95. This push generates a voltage in a piezoelectric device in the pushed part buried in the pressure detecting sheet 95, and the push is detected by sensing the voltage.
Since the support plate 60 is made of an elastically deformable material, it deforms so as to be dented in the pushed part as shown in
When the key top 220 is inclined to bring an inclination detector 50 into contact with the support plate 60, the inclination can be detected in a manner similar to the above by the pressure detecting sheet 95.
As described above, the input apparatus 200 of the present embodiment enables stabler input. The inclination of the key top 220 for information input becomes easier.
As shown in
The eighth embodiment will be described below as an embodiment wherein the inclination detectors of the input key according to the present invention form part of the opposite surface in the key top to the support plate and are comprised of a key-top-side slope portion formed so as to increase the distance to the support plate from the interior side to the exterior side.
The column 234 stands vertically to the support plate 60 and the peripheral part of the key top 220 is connected to the upper end of the column 234 through the key top periphery support 233. In this structure, the key top 220 is held with a constant clearance from the support plate 60 in a state in which no force is exerted on the key top 220.
The key top periphery support 233 is made of an elastically deformable material, e.g., a spring, synthetic rubber, soft plastic, soft vinyl, or the like. For this reason, when the key top 220 is pushed in an arbitrary direction, as shown in
Since the eighth embodiment as described above facilitates the contact with the opposed support plate 60 by provision of the key-top-side slope portion 240, it presents the effect of capability of surely carrying out the detection of contact through the use of electrodes 53, 55 or the like.
The inclination detectors according to the present invention do not always have to be placed on the key top 220 side, but may be formed on the support plate 60 side as shown in
Furthermore, the inclination detectors according to the present invention may be formed on both sides of the key top 220 side and the support plate 60 side. Namely, they may be comprised of slope portions formed in the slope shape on the respective sides of key top 220 side and support plate 60 side so as to increase the distance to the key top 220 and to the support plate 60 from the interior side toward the exterior side, with effect similar to that in the examples of
Incidentally, each of the above embodiments is preferably configured to be able to feed the up-to-date information of the conversion tables about the input keys back to the user during the push operation on the input key by the user. A configuration with such feedback function of the up-to-date information of conversion tables to the user will be described below. As shown in
The feedback is desirably carried out, for example, at a time of a change in assignment of plural input information elements to the input keys according to frequencies of use or the like, or at timing immediately after manipulation of the F key 162 in
The disclosure of Japanese Patent Application No. 2004-24165 filed Jan. 30, 2004 including specification, drawings and claims, the disclosure of Japanese Patent Application No. 2004-24193 filed Jan. 30, 2004 including specification, drawings and claims, and the disclosure of Japanese Patent Application No. 2004-294230 filed Oct. 6, 2004 including specification, drawings and claims are incorporated herein by reference in its entirety.
Number | Date | Country | Kind |
---|---|---|---|
2004-024165 | Jan 2004 | JP | national |
2004-024193 | Jan 2004 | JP | national |
2004-294230 | Oct 2004 | JP | national |
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4514600 | Lentz | Apr 1985 | A |
5468924 | Naitou et al. | Nov 1995 | A |
5691517 | Yamamoto et al. | Nov 1997 | A |
5744765 | Yamamoto | Apr 1998 | A |
5952628 | Sato et al. | Sep 1999 | A |
5952631 | Miyaki | Sep 1999 | A |
6266046 | Arita | Jul 2001 | B1 |
6399904 | Mimata | Jun 2002 | B1 |
6613990 | Kawasaki | Sep 2003 | B2 |
Number | Date | Country |
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2003-296001 | Oct 2003 | JP |
Number | Date | Country | |
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20050167251 A1 | Aug 2005 | US |