1. Field of the Invention
This invention generally relates to an input device which can be applied to an electronics device such as a mobile terminal device like a cellular phone or a PDA (Personal Digital Assistance), a personal computer, an electrical component of a car, or a game machine.
2. Description of the Related Art
There are some types of input devices for an electronics device, as typified by a mouse and so on. Japanese Patent No. 3530764 and Japanese patent Application Publication No. 2003-306149 disclose examples of the input devices. It is necessary to reduce the size or the thickness of the input device in order to apply the input device to a small electronics device.
For example, it is necessary to reduce number of switches or to remove movable portions in order to reduce the size or the thickness of the input device.
However, a function of the input device is decreased and operating feeling is degraded, when the number of switches is reduced or movable portions are removed. That is, an operator can operate the input device easily and can carry out many operations with the input device, if there are as many as switch functions and rotary portions.
The present invention provides an input device that has multiple functions, has high operability and has small thickness and size.
According to an aspect of the present invention, preferably, there is provided an input device including an operation portion, a holding portion, a detection portion and at least a switch. The holding portion holds the operation portion so that the operation portion is rotatable around a given axis. The detection portion detects a rotational position of the operation portion with respect to the holding portion. A condition of the switch changes according to an external force exerted to the operation portion.
In accordance with the present invention, operability of the input device is improved because the operation portion is rotatable. And it is possible to operate multiple functions with the input device because a signal is output from the switch and the detection portion.
According to another aspect of the present invention, preferably, there is provided an input device including an operation portion, a holding portion, and a detection portion. The holding portion holds the operation portion so that the operation portion is rotatable around a given axis. The detection portion detects a rotational position of the operation portion with respect to the holding portion. At least a part of the detection portion is provided on a facing surface of the operation portion and on a facing surface of the holding portion. The facing surfaces face to each other.
In accordance with the present invention, the input device is downsized and particularly the thickness of the input device is reduced, because the detection portion is provided on the facing surfaces of the operation portion and the holding member.
According to another aspect of the present invention, there is provided an electronics device including an operation portion, a holding portion, and a detection portion. The holding portion holds the operation portion so that the operation portion is rotatable around a given axis. The detection portion detects a rotational position of the operation portion with respect to the holding portion. At least a part of the detection portion is provided on a facing surface of the operation portion and on a facing surface of the holding portion. The facing surfaces face to each other.
Preferred embodiments of the present invention will be described in detail with reference to the following drawings, wherein:
A description will now be given with reference to accompanying drawings, of embodiments of an input device in accordance with the present invention.
A description will be given, with reference to
As shown in
The main body 20 has an operation portion 30, a holding member 40, an electrical resistor 50, a conductive coupler 60 as a first conductive coupler, and a conductive coupler 70 as a second conductive coupler. The operation portion 30 and the holding member 40 are made of an electrically insulating material such as a resin, and are formed to be a disk. The electrical resistor 50 is formed on a facing surface 30A of the operation portion 30 facing to the holding member 40. The conductive couplers 60 and 70 are formed on a facing surface 40A of the holding member 40 facing to the operation portion 30.
A through-hole 31, in which a support shaft 41 of the holding member 40 is inserted, is formed at the center of the operation portion 30, as shown in
The support shaft 41 projects from the center of the holding member 40, as shown in
The electrical resistor 50 is formed linear, as shown in
The conductive couplers 60 and 70 are made of such as copper pattern or an aluminum pattern. The conductive coupler 60 is formed along a circumference of a circle around the support shaft 41 on the facing surface 40A of the holding member 40. The conductive coupler 70 has a spiral shape inside of the conductive coupler 60.
The electrical resistor 50 and the conductive couplers 60 and 70 are in touch with each other and are connected electrically, when the support shaft 41 is inserted into the through-hole 31 and the operation portion 30 is held by the holding member 40.
Here, a connecting points of the electrical resistor 50 and the conductive couplers 60 and 70 change as shown in
A distance L between the connecting points of the conductive couplers 60 and 70 the electrical resistor 50 gets lower and lower, when the operation portion 30 rotates in a direction R1 from a position shown in
The switch member 100 is fixed to a surface 30B of the operation portion 30, as shown in
An electrical system of the input device 10 has, for example, a variable resistor 55, an amplifier 301, an A/D converter 302, a switch SW, a processor unit 310 and so on, as shown in
The variable resistor 55 has the electrical resistor 50 and the conductive couplers 60 and 70. One of the conductive couplers 60 and 70 is coupled to an electrical power supply Vcc. The other is coupled to a grand GND. A voltage Va in a case where the electrical resistor 50 is positioned at a given position is output to the amplifier 301. The voltage Va changes according to the change of the electrical resistance between the conductive couplers 60 and 70.
The amplifier 301 amplifies the voltage Va by a given gain and outputs the amplified voltage to the A/D converter 302. The A/D converter 302 converts an analog signal into a digital signal, and outputs the digital signal to the processor unit 310.
The switch SW has the switch member 100 mentioned-above and is coupled electrically to the processor unit 310. For example, a current is provided to the switch SW when the switch member 100 is pressed to the operation portion 30. And the current is not provided to the switch SW when the switch SW is relaxed.
The processor unit 310 has a processor (CPU) 311, an interface circuit 312, a memory 313 and so on. The interface circuit 312 outputs a data to an electronics device 500. The memory 313 stores a program for creating information to be fed into the electronics device 500. The processor 311 executes the program stored in the memory 313, and creates an input-code (input-information) to be fed into the electronics device 500, according to a data from the A/D converter 302 and a line connection status of the switch SW. The processor 311 outputs the input-code to the electronics device 500 through the interface circuit 312. Other method for creating the input-information may be adopted.
The input device 10 is, for example, applied to such as a cellular phone, as shown in
For example, an operator of the cellular phone 500A can move a pointer displayed on the display 502 to a desirable position and can operate desirably, when the operator rotates the operation portion 30 of the input device 10 and presses the switch member 100.
Being different from the conductive coupler 70, a conductive coupler 70A as the second conductive coupler shown in
It is, therefore, possible to form the conductive coupler 70A easily. And it is possible to sequentially change the electrical resistance between the conductive couplers 60 and 70 according to the rotation of the operation portion 30. An electrical system of the input device may be as same as that mentioned above.
Next, a description will be given of an input device in accordance with another embodiment, with reference to
Two conductive couplers 70B are provided separately on a circumference of which center is shifted with respect to the center (support shaft 41) of the facing surface 40A of the holding member 40.
The electrical resistor 50 is provided on the facing surface 30A of the operation portion 30 (not shown) corresponding to the conductive couplers 70B, and is extending along the diameter direction of the operation portion 30.
Therefore, an electrical resistance between one of the conductive couplers 70B and the conductive coupler 60 is different from that between the other conductive coupler 70B and the conductive coupler 60. And one of the electrical resistances is reduced when the other one is enlarged because of the rotation of the operation portion 30. It is possible to detect the rotational position of the operation portion 30 with high accuracy, when the electrical resistances are converted into electrical signals and a differential between the signals is calculated.
An electrical system of the input device is shown in
The variable resistors 55A and 55B output voltages Va1 and Va2. The voltages are amplified by amplifiers 301A and 301B respectively and are fed into an A/D converter 302A. The A/D converter 302A outputs digital signals of the voltages Va1 and Va2 to the processor unit 310. The processor unit 310 creates an input-information to the electronics device 500 according to the voltages Va1 and Va2 and the condition of the switch SW.
As shown in
Electrical resistances between the conductive couplers 60 and 7OC1 and between the conductive coupler 60 and 70C2 are enlarged and electrical resistances between the conductive coupler 60 and 70D1 and between the conductive couplers 60 and 70D2 are reduced, when the operation portion 30 rotates in a direction R1. It is, therefore, possible to detect the rotational position and the rotational direction of the operation portion 30 with high accuracy, by using a change of the electrical resistances.
Four conductive couplers 70E are arranged at even intervals in a circumferential direction on the facing surface 40A of the holding member 40, as shown in
Each of the electrical resistances between the conductive coupler 60 and the four conductive couplers 70E is enlarged, when the operation portion 30 rotates in the direction R1. For example, it is possible to detect the rotational position of the operation portion 30 with high accuracy, by calculating an average of the electrical resistances.
A description will be given of an input device in accordance with another embodiment of the present invention, with reference to
As shown in
On the other hand, a conductive coupler 250 is provided on the circumference of the facing surface 30A of the operation portion 30 as shown in
The contact members 260A through 260D and the conductive coupler 250 are arranged facing so as to be electrically contactable to each other, and configure a switch.
One of the contact members 260A through 260D is coupled to the conductive coupler 250, when the operation portion 30 is under a force so as to incline.
All of the contact members 260A through 260D may be coupled to the conductive coupler 250 when the operation portion 30 is pressed.
The operation portion 30 may be elastically deformable, and one of the contact members 260A through 260D is coupled electrically to the conductive coupler 250 when the operation portion deforms with a force of a finger.
As mentioned above, the switch including the contact members 260A through 260D and the conductive coupler 250 is provided on the facing surface 30A of the operation portion 30 and on the facing surface 40A of the holding member 40. And it is possible to reduce the thickness of the input device and to generate various signals with various operations to the operation portion 30.
A description will be given of an input device in accordance with another embodiment of the present invention, with reference to
The input device has contact patterns 150A through 150H on the facing surface 30A of the operation portion 30, instead of the electrical resistor 50 and the conductive couplers 60 and 70, as shown in
As shown in
As shown in
As shown in
As shown in
The switch member 100 mentioned above and the switch shown in
The embodiments mentioned above include but not limited to the case where the operation portion has a disk shape. The operation portion may have other shapes such as a wheel.
The embodiments mentioned above include but not limited to the case where the electrical resistor is provided on the operation portion and the conductive coupler is provided on the holding member. -The electrical resistor may be provided on the holding member and the conductive coupler may be provided on the operation portion.
The embodiments mentioned above include but not limited to the case where the electrical resistor is formed linear. The electrical resistor may have other shapes such as a curved shape.
The embodiments mentioned above include but not limited to the case where the first conductive coupler is arranged outside of the second conductive coupler. The first conductive coupler may be arranged inside of the second coupler.
The embodiments mentioned above include but not limited to the case where the input device has the A/D converter, processor unit and so on. These components are provided in the electronics device.
The embodiments mentioned above include but not limited to the case where the contact patterns 150A through 150H are provided on the operation portion 30 and the contact patterns are provided on the holding member 40. The contact patterns 150A through 150H may be provided on the holding member 40 and the contact patterns 160 may be provided on the operation portion 30.
The embodiments mentioned above include but not limited to the case where the cellular phone is described as an electronics device. The input device may be applied to various electronics devices such as a mobile terminal device like a cellular phone or a PDA, a personal computer, an electrical component of a car, or a game machine.
The embodiments mentioned above include but not limited to the case where the detection portion of a rotational position is a type of contact. An optical sensor may detect a rotational position of the operation portion and the holding member without contact.
While the above description constitutes the preferred embodiments of the present invention, it will be appreciated that the invention is susceptible of modification, variation and change without departing from the proper scope and fair meaning of the accompanying claims.
The present invention is based on Japanese Patent Application No. 2005-314747 filed on Oct. 28, 2005, the entire disclosure of which is hereby incorporated by reference.
Number | Date | Country | Kind |
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2005-314747 | Oct 2005 | JP | national |