FR3078421A1 - COMPUTER MOUSE COMPRISING AT LEAST ONE VERIN BETWEEN THE SOLE AND THE HOUSING - Google Patents

Abstract

Mouse (1) for a computer (101) comprising a sole (2) and a housing (3) movable relative to the sole (2), characterized in that it comprises at least one jack (31, 32, 33, 34) of which a first end (35) is fixed to the sole (2) and a second end (36) is fixed to the housing (3), so that a displacement of the housing (3) relative to the sole (2) ) causes compression or extension of said cylinder (31, 32, 33, 34).

Description

Computer mouse comprising at least one jack between the sole and the housing

Technical field of the invention

The invention relates to an improved mouse for a computer comprising at least four degrees of freedom. The invention also relates to a computer system comprising such a mouse. Finally, the invention relates to a method of using such a mouse.

State of the art

To use certain three-dimensional software, such as computer-aided design software or to play certain video games, the use of an advanced mouse is known comprising at least four degrees of freedom (in other words four axes). Such a mouse comprises a sole carrying a housing to constitute a unit movable in translation in a plane along two perpendicular horizontal axes, like the standard so-called two-dimensional mice. The housing of such a mouse is movable relative to the sole, so as to be able to tilt by turning around a horizontal longitudinal axis, and by turning around a horizontal transverse axis, which constitutes two additional axes. The mouse can emit four information signals for each of its degrees of freedom, which offers possibilities for controlling particularly advanced software or video games.

Such a mouse is advantageous in that it allows more varied uses than a simple traditional two-dimensional mouse. However, there is a need for better interaction between the user and their computer. Thus, manufacturers seek to increase the diversity of instructions that the user can transmit to a computer and, conversely, the diversity of information that the computer can transmit to its user.

Subject of the invention

The object of the invention is to provide a computer mouse and a method of using such a mouse overcoming the above drawbacks and improving the mice and the methods of use known from the prior art.

To this end, the invention relates to a mouse for a computer comprising a sole and a housing movable relative to the sole, the mouse comprising at least one actuator, a first end of which is fixed to the sole and a second end of which is fixed. to the housing, so that a displacement of the housing relative to the sole causes compression or extension of said cylinder.

The mouse may include four jacks each having a first end attached to the sole and a second end attached to the housing.

The four cylinders can each extend along an axis, the four axes being parallel to each other. The four cylinders can be arranged at the four corners of a square of the sole or the housing.

The at least one actuator can comprise a spring, in particular a helical spring.

The at least one actuator may comprise an electrical connection capable of transmitting to said actuator a command to modify a height of the actuator and / or to modify a stiffness of the actuator and / or to modify a compression amplitude or d extension of the jack.

The at least one actuator may comprise an electrical connector capable of transmitting from said actuator information on the compression height of said actuator.

The mouse may include a microcontroller electrically connected to said at least one actuator.

The invention also relates to a computer system comprising a computer, a screen and a mouse as defined above.

The invention also relates to a method of using a mouse as defined above, the method comprising a step of tilting the housing relative to the sole and / or a step of moving the housing, in particular for driving of the housing, perpendicular to a plane along which the mouse is able to be moved.

The invention also relates to a method of using a mouse as defined above, the method comprising a step of controlling modification of a height of the jack and / or modification of a stiffness of the jack and / or modification of a compression amplitude or extension of the jack, following an event produced by computer software.

The invention also relates to a computer program product comprising instructions which, when the program is executed by a computer, lead the latter to implement a method of use as defined above.

The invention also relates to a recording medium readable by a computer or a mouse comprising instructions which, when executed by a computer or a mouse, lead the latter to carry out a method. of use as defined above.

Brief description of the drawings

These objects, characteristics and advantages of the present invention will be described in detail in the following description of a particular embodiment made without limitation in relation to the attached figures, among which:

Figure 1 is a symbolic view of a computer system according to an embodiment of the invention.

Figure 2 is a three-dimensional view from above of a six-axis mouse according to an embodiment of the invention.

Figure 3 is a three-dimensional view from below of the mouse.

Figure 4 is a schematic top view of a mouse sole with four jacks.

Figure 5 is a schematic view of a cylinder.

Description of an embodiment

FIG. 1 illustrates a computer system 100 comprising a computer 101, a mouse 1 and a screen 102, the screen and the mouse being connected to the computer 101. By “connected”, it is understood that these elements are connected to each other by so that we can exchange information. Although represented by link lines 103 in FIG. 1, these links can be wireless links. The computer 101 comprises a memory 104 and a microprocessor 105, in particular capable of processing information signals emitted by the mouse 1. The screen is capable of projecting an image comprising a pointer (in other words, a cursor) that the you can move on the screen by operating the mouse.

As can be seen in FIGS. 2 and 3, the mouse 1 comprises a sole 2 carrying a top casing 3 which has a generally rounded shape favoring handling by the user. The sole 2 has a flat lower face 4 by which it is supported on a substantially horizontal plane, such as a table or a mouse pad, identified by the two perpendicular horizontal axes x and y. Mouse 1 is therefore mobile in translation on this horizontal plane along the two perpendicular horizontal axes x and y. It is also movable in rotation about an axis normal to this plane, namely the yaw axis z.

The housing 3 can be tilted in a rolling movement relative to the sole by pivoting about the horizontal transverse axis x, and it can be tilted in a pitching movement by pivoting around the horizontal longitudinal axis y . The housing 3 can also be moved relative to the sole perpendicular to the plane on which it is supported. If this plane is horizontal, the box can therefore be moved vertically. The user can press with his hand to push, in other words push, the housing towards the support plane. When the user releases the pressure on the housing, it returns to its original position thanks to an elastic return.

In general, the housing 3 comprises a housing body 5 supporting a set of actuators as well as a so-called upper printed circuit, which is rigidly secured to this housing body. The housing body 5 comprises a left lateral flank 7, on which rests the thumb of a user grasping the mouse. This left lateral flank 7 comprises a lever 8, located in the front part and extending in a direction substantially parallel to the axis x, so as to be manipulated by the thumb of the user. The handle 8 is movable in rotation around the vertical axis z and around the transverse axis y. The housing body 5 also includes a domed upper face 11, which together with the left lateral flank 7 delimits a blunt edge 12 carrying two push buttons 13 and 14 located substantially in the middle of the left lateral flank 7, and which can also be actuated by the user's thumb. The upper front part of the housing body carries on the one hand a rotary wheel 16 which can be manipulated by the middle finger or the index finger of the user having the mouse in hand, as well as an additional push button 17 located above the wheel 16 , and that the user can also activate with his middle finger or index finger. Alternatively, the mouse could include more or less buttons or actuators and / or these buttons could be positioned differently on the mouse. For example, a mouse similar to the one we are describing could be obtained by symmetry so that it is suitable for left-handers.

The curved upper face 11 of the housing body 5 is covered by an additional curved and flexible plate 18, the front part of which has two arms 19 and 21 located on either side of the knob 16 and of the push button 17. These two branches 19 and 21 respectively constitute a so-called left click key and a so-called right click key respectively operable by the index and the middle finger of a right-handed user having the mouse in hand. As visible in FIG. 2, the two branches 19 and 21 are spaced from the front end of the housing body 5, which is here materialized in particular by a front edge 23 having a curved shape oriented transversely. The edge 23 is thus separated longitudinally from each of these keys 21 and 22 respectively by two support zones marked by 24 and 26 these support zones forming an integral part of the front of the housing body 5. The fact that the keys left and right clicks are separated from the front end of the housing 3 by two support zones 24 and 26 allows the user to tilt the housing 3 in roll by exerting forces directly on these support zones 24 and 26, that is to say without risk of clicking unexpectedly.

Alternatively, the mouse may include any number of buttons that the user can press with any finger of the hand. It may also not include a knob 16 or a lever 8 as described above. The shape of the case can be arbitrary as long as it allows it to be grasped by a user's hand.

As regards the sole 2, it also comprises a sole body 25 supporting a so-called lower printed circuit as well as various components. As can be seen in particular in FIG. 3, the lower face 4 of this sole body is equipped with a set of pads 27 facilitating its sliding. It is also equipped with a laser type displacement sensor, identified by 28, and by which the translational movements along the x and y axes relative to the support are measured. Furthermore, this sole 2 comprises at its front part a connector 29 of the mini-USB type, by means of which the mouse can be connected to a computer so as to transmit its information, and / or to recharge a battery integrated in this mouse to allow it to exchange information with the computer over a wireless link.

The so-called lower printed circuit is rigidly secured to the sole and itself carries different components including an accelerometer called lower rigidly secured to this printed circuit. This lower printed circuit also carries components specific to the mini-USB connector, to the laser sensor 28, and to other components. Similarly, the so-called upper printed circuit is rigidly attached to the housing body 5. This upper printed circuit carries an accelerometer called upper, also rigidly attached to the printed circuit that carries it, as well as a set of components specific to the thumbwheel 16, the lever 8 and the pushbuttons 13, 14, 17. These two printed circuits are electrically connected to each other by a connector, so that the information coming from the upper printed circuit, such as the depressed state of one or other of the left and right clicks, the position of the wheel 16 or even the position of the lever 8 are transmitted to the lower printed circuit. As a note, the position (in other words the inclination) of the lever 8 can be determined by a means for measuring an inclination known per se.

The two accelerometers are used jointly by a computing unit, such as a microcontroller, equipping for example the lower printed circuit, to determine the inclination of the housing 3 relative to the sole.

2.

The two accelerometers are advantageously identical electronic components so as to simplify the processing of the signals which they deliver. They are advantageously accelerometers in the form of MEMS electronic components of the LIS331DLH type sold under the brand ST®. Each accelerometer supplies signals representative of the accelerations which it undergoes along three orthogonal axes which are specific to it, and these signals are sent to the microcontroller equipping the lower printed circuit. The signals from the accelerometers are processed by the microcontroller to determine the inclination of the housing 3 relative to the sole 2, on the one hand around the x axis, and on the other hand around the y axis. To this end, the microcontroller retrieves at all times the signals representative of the acceleration undergone by the upper accelerometer and by the lower accelerometer along the x axis. It is therefore understood that the accelerometers associated with the microcontroller of the mouse constitute a means of measuring the inclination of the housing 3 relative to the sole 2.

The sole 2 is physically connected to the housing 3 by means of four jacks 31, 32, 33, 34 illustrated in particular in FIG. 4 which could also be called "pistons". “Cylinder” means a mechanical device the height of which can vary. Each cylinder 31, 32, 33, 34 has a first end 35 fixed to the sole 2 and a second end 36 fixed to the housing 3. The four cylinders are preferably identical. They each extend along an axis parallel to the yaw axis z, this axis being vertical when the mouse rests on a horizontal plane. They are arranged at the four corners of a square of the sole 2. Thus, the weight of the user's hand resting on this housing is evenly distributed between the four jacks. Advantageously, the square considered has a side length L of the order of 1.5 to 2.0 cm, in particular 1.8 cm.

As illustrated in FIG. 5, the jack conventionally comprises an external shell 37, an internal shell 38 capable of sliding inside the external shell 37, and a spring 39, arranged between the external shell 37 and the internal shell 38. The height H of the jack is the distance separating the first end 35 from the second end 36 along the axis z. The compression or extension of the spring 39 therefore makes it possible to vary the height H of the jack. Preferably, the spring is a helical spring. The jack may have a generally cylindrical outer casing with a height H of the order of 2.0 cm (in the absence of any stress). The base of the cylinder can have a circular shape or a square shape. The diameter D or the side of this base can have a dimension of the order of 0.3 to 0.4 cm, in particular 0.36 cm.

As a variant, the mouse could comprise only three jacks, in particular three jacks distributed at the vertices of an equilateral triangle of the sole 2. In a simplified version, the mouse could also include only two jacks, the housing would then be able to pivot by relative to the sole only by a rolling movement or by a pitching movement according to the position of these two jacks or else to be pressed vertically towards the sole. Finally, the mouse could also include a single jack so that the housing would only be able to be pressed vertically towards the sole.

When the user of the mouse rotates the housing 3 relative to the sole 2, the jacks on the side towards which the housing is inclined are compressed while the others extend or remain stationary. In order to allow the housing to pivot relative to the sole, a certain clearance in the jack and / or at the interface between the jack and the case and / or at the interface between the jack and the sole can be provided. For example, the first end 35 of the jack can be in sliding contact before the sole 2 and / or the second end 36 can be in sliding contact with the housing 3. Thus, the fixing between the first end 35 of the jack and the sole 2 and / or the fixing between the second end 36 of the jack and the housing may allow slight mobility between the jack and the sole or between the jack and the case. When the user pushes the housing 3 towards the sole 2, the four jacks are compressed simultaneously. A rotation of the housing 3 relative to the sole 2 around the yaw axis z is logically impossible.

Each actuator further comprises an actuator electrically connected to the microcontroller of the mouse via an electrical connector 40. This actuator can modify the height of the actuator, that is to say impose a compression or an extension of the actuator to against the force exerted by the user on the housing. As a variant or in addition, the actuator can modify the stiffness of the jack, in other words the stiffness of the spring 39 of the jack. If the stiffness of the cylinder is increased, greater effort will be required to compress it. Finally, as a variant or in addition, the actuator can modify the compression and / or extension amplitude of the jack, that is to say modify the maximum stroke of the jack in compression or in extension.

Optionally, each jack can also include a means for measuring its height 6. In this case, the measuring means is able to transmit this information to the mouse microcontroller via the electrical connector 40. This information can be used by the microcontroller, in addition to the signals from the accelerometers to determine the inclination of the housing 3 relative to the sole 2 with greater precision or to measure the depression of the housing relative to the sole.

Finally, the mouse is able to transmit seven information signals to the computer 101, each corresponding to a degree of freedom of the mouse to which are added binary information signals for each of the buttons of the mouse and for the wheel. . A first information signal includes information relating to the translational movement of the mouse parallel to the transverse axis x. A second information signal includes information relating to the translational movement of the mouse parallel to the longitudinal axis y. A third information signal includes information relating to the rotation of the housing 3 around the transverse axis x. A fourth information signal includes information relating to the rotation of the housing 3 around the longitudinal axis y. A fifth information signal includes information relating to the depression of the housing 3 parallel to the longitudinal axis y. A sixth information signal includes information relating to the rotation of the lever 8 around the vertical axis z. A seventh information signal includes information relating to the rotation of the lever 8 around the longitudinal axis y.

The mouse can be used 1 to control software making it possible to represent a three-dimensional object such as for example computer-aided design software or a video game.

The depression of the housing relative to the sole can be associated for example with a zoom control on the three-dimensional object. The rotation of the upper housing 3 of the mouse relative to the sole 2 can be associated with a control of rotation of the three-dimensional object displayed on the screen. Thus, the user can rotate this object along two perpendicular axes to observe it from all angles. If during its rotation the three-dimensional object as represented on the computer screen encounters an obstacle which should disturb its rotation, an actuation of certain jacks of the mouse makes it possible to feel the contact of the obstacle against the to the user. For example, to materialize a difficult rotation of the three-dimensional object to the right, it is possible to send a command order to the two jacks 32, 34 to increase its stiffness. To materialize an impossible rotation of the three-dimensional object beyond a certain angle to the right, a command can be sent to the two jacks 32, 34 to reduce the maximum compression of these two jacks (i.e. say to limit the compression stroke of these two cylinders). To materialize the impossibility of moving the three-dimensional object, the four jacks could be locked in position.

These examples can of course be transposed to a rotational movement in any other direction. Similarly, if the rotation of the housing 3 is associated not with a rotational movement of the three-dimensional object but with a translational movement, the interactions described above can be adapted to materialize a translational movement made more difficult, or even impossible, in one or more directions.

Another example of use can be achieved when the three-dimensional object is struck or by another three-dimensional object. In this case, the shock can be materialized by actuation of one or more cylinders depending on the origin of the shock. The user therefore perceives a haptic feedback, that is to say a slight vibration, which completes their visual experience.

The use of such a mouse therefore allows its user to further immerse themselves in the virtual space displayed on the computer screen. It can therefore transmit order orders more efficiently to the computer and, conversely, receive more information from the latter.

According to another example of using the mouse, the stiffness of the jacks can be associated with a user profile. Thus, each user of the mouse can adjust the resistance to pivoting of the housing relative to the sole 10 according to his preferences and / or his dexterity. All the jacks of the mouse can also be locked simultaneously so as to temporarily deactivate the possibility of pivoting the housing relative to the sole. Thus, the mouse can be temporarily transformed into a traditional mouse.

Claims (12)

1. Mouse (1) for a computer (101) comprising a sole (2) and a housing (3) movable relative to the sole (2), characterized in that it comprises at least one jack (31, 32, 33, 34) of which a first end (35) is fixed to the sole (2) and a second end (36) is fixed to the housing (3), so that a displacement of the housing (3) relative to the sole (2) causes compression or extension of said cylinder (31, 32, 33, 34). 2. Mouse (1) according to the preceding claim, characterized in that it comprises four jacks (31, 32, 33, 34) each having a first end (35) fixed to the sole (2) and a second end (36 ) attached to the housing (3). 3. Mouse (1) according to the preceding claim, characterized in that the four jacks (31,32, 33, 34) each extend along an axis (z), the four axes (z) being mutually parallel and / or in that the four jacks (31, 32, 33, 34) are arranged at the four corners of a square of the sole (2) or of the housing (3). 4. Mouse (1) according to one of the preceding claims, characterized in that the at least one actuator (31, 32, 33, 34) comprises a spring (39), in particular a helical spring (39). 5. Mouse (1) according to one of the preceding claims, characterized in that the at least one actuator (31, 32, 33, 34) comprises an electrical connection (40) capable of transmitting to said actuator (31, 32, 33, 34) a command to modify a height of the jack and / or to modify a stiffness of the jack and / or to modify a compression or extension amplitude of the jack. 6. Mouse (1) according to one of the preceding claims, characterized in that the at least one actuator (31, 32, 33, 34) comprises an electrical connector (40) capable of transmitting from said actuator height information compression of said cylinder. 7. Mouse (1) according to one of the preceding claims, characterized in that it comprises a microcontroller electrically connected to said at least one actuator (31,32, 33, 34). 8. Computer system (100) comprising a computer (101), a screen (102) and a mouse (1) according to one of the preceding claims. 9. Method of using a mouse (1) according to one of claims 1 to 7, characterized in that it comprises a step of tilting the housing (3) relative to the sole (2) and / or a step of moving the housing (3), in particular of driving the housing (3), perpendicular to a plane along which the mouse (1) is able to be moved. 10. A method of using a mouse (1) according to one of claims 1 to 7, characterized in that it comprises a step of controlling modification of a height of the jack and / or modification of a stiffness of the cylinder and / or modification of a compression or extension amplitude of the cylinder, following an event produced by software on a computer. 11. A computer program product comprising instructions which, when the program is executed by a computer (101), lead the latter to implement the method of use according to one of claims 9 to 10. 12. Recording medium readable by a computer (101) or a mouse (1) comprising instructions which, when executed by a computer (101) or a mouse (1), drive the latter or the latter to implement the method of use according to 10 one of claims 9 to 10.