SE529310C2 - Arrangement is for input of control signals to peripheral unit and has casing which functions as support for hands and forearms of user when he or she works with arrangement - Google Patents

Abstract

The arrangement is for the input of conical siganls to a peripheral unit and has a casing (4) which functions as a support for the hands and forearms of a user when he or she works with the arrangement. Two buttons (5,6) are used for generating further control signals. A band/loop (1) is located in an aperture and a user with a hand part can move it, thus producing a movement of an indicator on the computer screen. Only a part of the band/loop is accessible through the aperture in the casing. The band/loop are suspended on two shafts. The arrangement is provided with sprung components at the ends of one of the shafts. A movement sensor for measurement of movement of the band is placed at the side of the shaft which is not suspended with the sprung components. The movement sensor can be of hte type found in optical standard mice.

Description

529 310 when it is desired to be able to generate an additional control signal for the peripheral unit by pressing the pointing surface in the vertical direction. Furthermore, the carriage gives the pointing surface a conformal behavior regardless of position along the axes and the carriage also gives the pointing surface a uniform behavior over the entire surface.

The canvas is kept taut by the shoulders and the sled. For example, and in part, this can be accomplished with resilient elements that hold the shoulders apart. To a further extent, this is achieved by the sled also being provided with resilient elements which stretch the infinite loop.

Devices where the control signal is generated by means of a rotatable and transversely displaceable rod are also known. Even in the case of these, an additional control signal can be generated by depressing the shaft vertically.

Furthermore, fixed touch plates are known. In these, the user can generate control signals to the peripheral device by moving a finger or the like over the touchpad. The detection of the movement is done in these by means of pressure-sensitive resistive or capacitive sensors.

A standard computer mouse is of course also known. Such a computer mouse is designed to move on a surface. The movement in different directions is detected and converted into electrical signals that are used to move, for example, a cursor or pointer arrow on a computer screen.

A standard computer mouse usually includes a ball that rotates as the mouse moves on a surface. The rotation of the ball can be detected by electrical or optical means. However, it is also known that a computer mouse can be constructed without using a bullet. For example, US-B1-6,281,882 discloses a computer mouse which optically senses the movement of the mouse on a surface without using a ball. 10 15 20 25 30 35 529 310 Input devices described above have certain disadvantages.

The standard computer mouse restricts the user to using the mouse on a desktop or other support surface. The use of such a computer mouse can lead to a static working position which can cause overexertion of the arm and hand used to maneuver the mouse. The devices described above that enable work with the hands directly in front of and near the body provide ergonomically advantageous working positions.

SUMMARY OF THE INVENTION An object of the invention is to provide a device of the type specified in the first paragraph above and which enables a lower working height relative to the table surface. A further object is to provide such a device which due to the lower height can be used together with other types of related devices such as for example keyboards.

The above objects are achieved with a device of the type described in the first paragraph above, the device being designed so that the device contains a pointing surface which can be moved in the plane and this device comprises a sensing means which senses the movement of the pointing surface and in response thereto. causes the device to generate control signals suitable for transmission to said peripheral unit so that the movement of the touch surface fulfills the same function as the movement of a standard computer mouse.

The infinite loop is mounted around two parallel rods. Since the infinite loop has a relatively large lateral extension, it is perceived as a wide band by the user. The movement of the band up and down, which typically corresponds to vertical movement of the pointer on a monitor, is endless as the loop is infinite in that joint. The lateral movement, which corresponds to the movement of the pointer to the right and left of the monitor, is finite. The touch surface thus has mechanical stops laterally.

According to an advantageous embodiment, the infinite loop with low friction can move around the two axes. The low friction is achieved either by the shafts having low friction against the loop or the shafts are rotating. A combination of these possible realizations is also possible.

According to another advantageous embodiment, the cloth is supported by a carriage which fills the loop between the axles. The carriage is suspended in the two parallel axes. The sledge slides with low friction along the two axles.

The carriage provides a more stable pointing surface which is needed as it is desirable to be able to generate an additional control signal for the peripheral unit by pressing the pointing surface in the vertical direction.

Furthermore, the carriage gives the pointing surface a conformal behavior regardless of position along the axes and the carriage also gives the pointing surface a uniform behavior over the entire surface.

The canvas is kept taut by the shoulders and the sled. For example, and in part, this can be accomplished with resilient elements that hold the shoulders apart. To a further extent, this is achieved by the sled also being provided with resilient elements which stretch the infinite loop.

It is advantageous if the infinite loop is placed behind a casing in which there is a window where the touch surface is accessible to the user. The window is smaller is the extent of the loop in the plane. The user can then rest his hands on the cover and with any hand move the touch surface in the desired way.

It is desirable that the device contain additional means to be able to generate additional control signals to the peripheral unit. With the cover it is possible to achieve this.

Buttons are then placed around that window with the touchpad. These buttons are mechanically connected to electronic switches which can then generate additional control signals to the peripheral unit.

It is necessary to provide the device with means which handle the problem of being able to reach over the entire screen laterally when the touch surface has mechanically reached its end position. This is typically done with a detector that notes when the end position is reached and then generates a control signal that moves the pointer on the screen to the desired side of the screen.

The device contains means which detect and read the movement of the loop. These detecting means may be, for example, an optical, resistive or capacitive type sensor.

According to a preferred embodiment of the invention, this detector is the same type of optical detector used in the standard computer mouse as mentioned above. In this realization, the optical sensor detects the motion of the loop. The sensor is then positioned so that it detects when the surface of the loop moves in front of the optical sensor. The motion read by the optical sensor then generates control signals to the peripheral device. The optical sensor is often a camera with an associated processing unit. The camera captures the pattern on the surface and the processing unit can then determine how these patterns move.

In the same way, it is possible with an optical sensor to detect that one of the axes is moving. This applies to both shaft rotation and translation.

According to an advantageous embodiment, it is possible to generate an additional control signal by pressing on the pointing surface, which then moves vertically. This vertical movement is detected, for example, by an electrical switch. Typically, this capability is used to generate a signal corresponding to "left-click" on a standard computer mouse. It is desirable that the pressure on the touchpad does not also generate a signal causing a movement of the pointer on the screen. Typically, this has been solved by positioning the optical sensor so that the touchpad moves straight towards the sensor when the touchpad is depressed. Since the loop only moves a short distance towards the optical sensor, the image in the optical sensor does not change and then no control signal is generated to the peripheral unit. This means that the optical sensor is placed under the infinite loop.

The invention comprises a device as above with a sensor placement and means which enable the optical sensor to be placed next to the loop without the optical sensor detecting that the loop moves when the pointing surface is pressed down.

This is advantageous as the total height of the device can be considerably reduced. The user can then work with his hands at a lower height above the table.

According to a preferred embodiment, only one of the shafts is movable in the vertical direction. The optical sensor is placed at the axis that is not movable. When the user presses the touchpad, the touchpad moves downward without the optical sensor seeing any movement. As the movement is short, the user does not perceive that the touchpad de facto moves more at one end than the other.

According to another preferred embodiment, only one end of the axles and the slide can move. The other end does not move if the user presses the touchpad. The optical sensor is located on the side of one of the shafts at the point where the shafts cannot move vertically. The shoulders are articulated at the end where they do not move vertically. The optical sensor then detects no movement when the touchpad is pressed. As the movement is short, the user does not perceive that the touchpad de facto moves more at one end than the other. 10 15 20 25 30 35 529 310 It is possible to achieve the same advantages with other types of motion detecting means than the optical sensor mentioned above.

The design as above provides a lower device. When designing a keyboard, it is known that it is ergonomically advantageous if the keyboard is as low as possible.

Keyboards therefore tend to get lower and lower. The various central controls mentioned above have a working height that does not allow the use of low key tables. If the keyboard is low, it ends up at a lower working height than the controller. Reaching the keyboard behind and lower than the controller becomes disadvantageous. A device as above solves this problem.

It should further be noted that the device can be incorporated in different types of solutions. The device can, for example, advantageously be integrated as part of a forearm support. It is also possible to realize solutions where the device is not integrated with any other parts.

These integrated solutions can then be advantageously combined with additional alternative solutions with the aim of providing the user with relief and other assistance.

The invention also relates to a combination of the device according to one of the embodiments described above and a peripheral unit.

The combination is arranged or programmed so that the movement of said pointing surface causes the peripheral unit to control at least one entity of the peripheral unit. The peripheral device may include, for example, a computer and a monitor. The combination may be arranged or programmed so that the manipulation of said first input means or the movement of the device on said surface causes a cursor or other graphic entity to move on said screen. According to the combination, the device is thus actively connected to a peripheral unit for controlling any entity. 10 15 20 25 30 35 529 310 BRIEF DESCRIPTION OF THE RELATIONS Fig. 1 shows a perspective view of an embodiment of the device according to the invention.

Fig. 2 schematically shows a perspective view of an embodiment of the invention.

Fig. 3 schematically shows a perspective view of a second embodiment of the device Fig. 4 schematically shows a side view of a second embodiment of the device Fig. 5 shows a perspective view of the device DESCRIPTION OF EMBODIMENTS OF THE INVENTION Fig. 1 shows a device according to the invention with a housing 4 which also functions as support for the hands and forearms when working with the device. Figure 1 shows an example with two additional buttons 5,6 which are used to generate additional control signals. The band / loop 1 is seen in an opening in the housing. The user can move the belt / loop 1 with any part of the hand and thereby effect a movement of the pointer on the computer screen. Only a part of the surface of the belt / loop 1 is accessible through the opening in the housing 4.

Fig. 2 schematically shows a first embodiment of the invention.

The strap / loop 1 is suspended on two shafts 2, 3. The device is provided with resilient elements 7, 8 at one end of the two shafts 2, 3. A motion sensor 11 which can measure the movement of 10 15 20 25 30 35 529 310 the belt 1 'is placed next to one of the shafts 2,3 at the end of the shafts 2,3 where the shafts are not suspended by resilient elements 7, 8. The motion sensor 11 may for example be the type of motion sensor present in standard optical mice.

Fig. 3 schematically shows a second embodiment of the invention.

The belt / loop 1 is suspended on two shafts 2, 3. The device is provided with resilient elements 9, 10 at the ends of one of the shafts 2, 3. A motion sensor 11 which can measure the movement of the belt 1 is located at that side of that of the shafts 2,3 which are not suspended by resilient elements 9,10. The motion sensor 11 can be, for example, the type of motion sensor found in standard optical mice.

Fig. 4 shows a schematic side view of a second embodiment of the invention. The belt / loop 1 is located under the housing 4. There is an opening in the housing through which the user can move the belt / loop. The strap / loop is suspended on two axles 2,3.

The device is provided with resilient elements 9, 10 at the ends of one of the shafts 2. A motion sensor 11 which can measure the movement of the belt 1 is placed at the side of that of the shafts 3 which is not suspended by resilient elements 9,10.

The motion sensor 11 can be, for example, the type of motion sensor found in standard optical mice. Below the loop is an electrical switch 12 that detects when the user presses the loop to generate a control signal which, for example, corresponds to a left click with a standard standard mouse.

Fig. 5 shows a perspective view of the device where the device is connected to a peripheral unit 13.

The invention is not limited to the described embodiments but can be varied and modified within the scope of the following claims.

Claims (8)

10 15 20 25 30 35 529 310 10 Patent claims A device for inputting control signals to a peripheral unit (13) with a pointing surface which is movable, by means of a finger or the like, which causes the device to generate control signals suitable for transmission to said peripheral unit (13) so that the movement of said pointing surface performs the same function as the movement of a standard computer mouse, where the pointing surface consists of a band / loop (1) or equivalent device, which is arranged around at least two separate rods or equivalent devices (2,3), which are translatably and rotatably arranged, where the pointing surface is arranged to be movable in the vertical direction relative to the plane of the pointing surface and then generate a further control signal suitable for transmitting to the peripheral unit, characterized in that means (11) for detecting movement of the loop (1) or shafts caused by movement of the pointing surface in the plane, placed next to the loop and one of the shoulders. A device according to claim 1, characterized in that at least one of the shafts (2,3) around which the loop (1) is arranged is partially or completely not movable in the vertical direction relative to the plane of the pointing surface, and that means (11) to detect the movement of the loop or axes, caused by movement of the pointing surface in the plane, placed where the axis is not movable in the vertical direction relative to the plane of the pointing surface. A device according to claim 2, characterized in that the entire one shaft (2,3) is not movable in the vertical direction relative to the plane of the pointing surface, and that means (11) for detecting the movement of the loop (1) or shafts, caused by movement of the pointing surface in the plane, placed next to the axis which is not movable in the vertical direction relative to the plane of the pointing surface. A device according to claim 2, characterized in that one end of the two shafts (2,3) is not movable in the vertical direction relative to the plane of the touch surface, and that means (11) for detecting the movement of the loop (1) or shafts, caused by movement of the pointing surface in the plane, is placed next to one of the shafts where it is not movable in the vertical direction relative to the plane of the pointing surface. A device according to claims 1-4, characterized in that means (11) for detecting the movement of the loop (1) or the shafts (2,3), caused by movement of the pointing surface in the plane, is an optical sensor. A device according to claims 1-5, characterized in that means (11) for detecting the movement of the loop (1) or the shafts (2,3), caused by movement of the pointing surface in the plane, is an optical sensor of a similar type as in a standard computer mouse. A combination, a device according to any one of the preceding claims and a peripheral unit (13), said combination being arranged or programmed so that movement of said touch surface causes the peripheral unit (13) to control at least one entity of the peripheral unit (13). 13). A combination according to claim 7, wherein said peripheral unit (13) includes a computer and a screen and wherein said combination is arranged or programmed so that the manipulation of said touch surface causes a cursor or other graphical entity to move on said screen.