NL2025036B1 - Handheld pointing device, weighing unit therefore, extension unit and combination of keyboard and extension unit - Google Patents

Abstract

The invention relates to a handheld pointing device comprising: a. a housing; b. an electronics module for converting position, orientation and/or displacement into coded form and transmitting the coded form to a computer; and c. a weight unit having an attachment member, wherein the housing includes an attachment member for attaching the weight unit to the housing, wherein the attachment members define a rotation axis for the weight unit, wherein the weight unit has a weight distribution such that a center of gravity is located at a non-zero distance from the rotation axis and/or such that a moment of inertia about a first axis perpendicular to the rotation axis is different from a moment of inertia about a second axis, and wherein the housing and the weight unit are configured to interchangeably attach the weight unit to the housing in at least three distinct angular orientations about the rotation axis.

Description

TITLE OF THE INVENTION Handheld pointing device, weighing unit therefore, extension unit and combination of keyboard and extension unit

BACKGROUND OF THE INVENTION The invention relates to input devices for computing devices, e.g. computers, such as a mouse and keyboard. The mouse is an example of a handheld pointing device including a housing and an electronic module accommodated by the housing for converting position, orientation and/or displacement of the housing into coded form and for transmitting the coded form as user input to a computing device. This allows for instance to control the position, orientation and/or displacement of a cursor or pointing arrow on a display of the computing device.

The keyboard is an example of a character input device including a housing and a plurality of buttons or keys for interacting with the fingers of a user, which buttons or keys are associated with at least one character and an electronic module accommodated by the housing for converting the interaction with a button or key into coded form and for transmitting the coded form as user input to a computing device. Both input devices are used by regular users for work and home related activities, such as reading and drafting documents and e-mails, etc. However, such input devices are also used for gaming purposes. With the increased professionalization of the gaming industry, the demands with respect to the input devices also increased. Hence, it is customary now to personalize the input devices to a high degree allowing to optimize the gaming experience or to increase the performance. For handheld pointing devices, this has resulted in the possibility to adjust the weight of the device and/or to adjust the center of gravity of the device as for instance shown in US2006/0202961A1 and US2017/0205900A1.

However, the current devices are too complex as they involve active positioning mechanisms to position the weight unit relative to the housing or do not provide sufficient freedom to adjust the weight, the center of gravity and/or the moment of inertia.

SUMMARY OF THE INVENTION In view of the above it is an object of the invention to provide a handheld pointing device allowing to easily adjust the weight, the center of gravity and/or the moment of inertia of the device.

According to a first aspect of the invention, there is provided a handheld pointing device for providing user input to a computing device, comprising: a. a housing; b. an electronics module accommodated by the housing for converting position, orientation and/or displacement of the housing into coded form and for transmitting the coded form as user input to the computing device; and c. a weight unit having an attachment member, wherein the housing includes an attachment member for attaching the attachment member of the weight unit to the housing, wherein the attachment members of the housing and the weight unit define a rotation axis for the weight unit, wherein the weight unit has a weight distribution such that a center of gravity of the weight unit is located at a non-zero distance from the rotation axis and/or such that a moment of inertia of the weight unit about a first axis perpendicular to the rotation axis of the weight unit is different from a moment of inertia of the weight unit about a second axis perpendicular to the rotation axis and different from the first axis, and wherein the housing and the weight unit are configured to interchangeably attach the attachment member of the weight unit to the attachment member of the housing in at least three distinct angular orientations of the weight unit about the rotation axis with preferably a smallest angle between two extreme angular orientations spanning all other intermediate angular orientations being at least 135 degrees, preferably at least 150 degrees, more preferably at least 165 degrees and most preferably at least 180 degrees.

In an embodiment, the attachment member of the weight unit and/or the attachment member of the housing is substantially circular or ring-shaped.

An advantage of at least one of the attachment members being circular or ring-shaped attachment member may be that it provides an easy to adjust angular orientation of the weight unit relative to the housing about the rotation axis without using a relatively large amount of space.

In an embodiment, the attachment member of the weight unit and/or the attachment member of the housing is or resembles a polygon having at least 3 or 4, for instance at feast 5, preferably at least 6, more preferably at least 8 and most preferably at least 10 segments. When a polygon shape is used, the shape is preferably a regular convex polygon, with preferably all angles being equal and with preferably all segments being of the same size. The shape is preferably cyclic, meaning that all corners lie on a single circle. The more segments the polygon shape has, the more it will also resemble a circular or ring shape, so that such shapes can also be described using these terms. The polygon shape may relate to a completely filled shape or a polygon ring having an opening in the middle.

It is further noted that substantially circular or ring-shaped does not necessarily mean that the circle or ring is complete or closed. An attachment member may for instance be formed of one or more circle or ring segments, wherein the one or more circle or ring segments span at least 135 degrees, preferably at least 150 degrees, more preferably at least 165 degrees and most preferably at least 180 degrees. In an embodiment, the handheld pointing device is a computer mouse configured to translate two-dimensional motion of the housing relative to a surface into motion of a pointer on a display of a computer.

In an embodiment, the housing and the weight unit are configured to attach the weight unit to the housing using the attachment device in at least three or four, preferably at least five, more preferably at least six, and most preferably an infinite number of different angular orientations of the weight unit about the rotation axis. The more possible angular orientations of the weight unit about the rotation axis, the easier the weight unit can be used to optimize the weight, the center of gravity and/or the moment of inertia of the device.

In an embodiment, an engagement between the attachment member of the weight unit and the attachment member of the housing is mainly based on friction. This allows an easy to attach and release weight unit. One of the attachment members may for instance include rubber material or any other elastically deformable material for engagement. Overcoming friction may not only be used for attaching and releasing, but may also be used to rotate the attachment member of the weight unit relative to the attachment member of the housing.

In an embodiment, an engagement between the attachment member of the weight unit and the attachment member of the housing is mainly based on magnetic or electrostatic forces. One of the attachment members may for instance include one or more (permanent) magnets and the other one of the attachment members may include one or more magnets or magnetizable material. Overcoming these magnetic or electrostatic forces is then required for attaching and releasing of the weight unit, but may also be used to rotate the attachment member of the weight unit relative to the attachment member of the housing between distinct angular orientations. However, it is also possible that the magnetic or electrostatic forces only provide an attracting force to keep the attachment members in frictional engagement and rotation of the attachment member of the weight unit relative to the attachment member of the housing is caused by overcoming said friction.

In an embodiment, the weight unit comprises a main body that mainly defines a weight distribution of the weight unit, wherein the attachment member of the weight unit is connected to or a part of the main body.

The main body may have a shape different from the corresponding attachment member. For instance, the attachment member may be ring shaped while the main body may be triangular, square or an irregular shape. However, the shape of the main body may be similar to the shape of the attachment member.

5 In an embodiment, the complete weight unit forms the attachment member, so that the main body and the corresponding attachment member have the same shape, which make the weight unit easy to handle. It also allows the possibility that the weight unit can be attached to the housing independent of which side of the weight unit faces towards the housing, so that a user does not have to worry about which side faces the housing to correctly attach the weight unit.

In an embodiment, the attachment member of the housing includes a recess for receiving the attachment member of the weight unit.

In an embodiment, the weight unit and the attachment member of the housing are both ring-shaped and configured to surround a sensor, e.g. an optical sensor, of the electronics module in the housing configured to measure a position, orientation and/or displacement of the housing relative to a reference. This has been found to be a position in which the weight, the center of gravity and/or the moment of inertia can be adjusted while minimizing the space required for the weight unit and the corresponding attachment member of the housing, so that the risk of having to design a handheld pointing device that is larger than a prior art handheld pointing device is minimized.

In an embodiment, the attachment member of the housing is configured to attach at least two separate weight units simultaneously, for instance two, three or even four weight units.

In an embodiment, the handheld pointing device may be combined with one or more of the following types of weight units: Type A: weight unit having a uniform weight distribution that affects the weight, the moment of inertia and possibly the center of gravity by attaching the weight unit to the housing, but which is not able to further adjust any of these parameters after attaching the weight unit to the housing by changing the angular orientation; Type B: weight unit having a weight distribution that affects the weight, the moment of inertia and the center of gravity by attaching the weight unit to the housing, but which is able to only adjust the center of gravity and the moment of inertia after attaching the weight unit to the housing by changing the angular orientation; Type C: weight unit having a weight distribution that affects the weight, the moment of inertia and possibly the center of gravity by attaching the weight unit to the housing, but which is able to only adjust the moment of inertia after attaching the weight unit to the housing by changing the angular orientation.

The type A weight unit preferably does not affect, or at least minimally affects the center of gravity, so that the type A weight unit can be mainly used for adjusting the weight of the handheld pointing device although this adjustment is then not caused by changing the angular orientation, but by adding or removing the weight unit. The main body of a type A weight unit is preferably circular or ring-shaped and of uniform thickness and density while the center of gravity of the weight unit coincides with the rotation axis. The type B weight unit is preferably mainly used to adjust the center of gravity of the handheld pointing device. The type B weight unit has a center of gravity at a distance from the rotation axis.

The type C weight unit is preferably mainly used to adjust the moment of inertia of the handheld pointing device. An example of a type C weight unit is a ring-shaped main body having first weight portions at 12 o'clock and 6 o'clock locations on the ring and having second weight portions at 3 o'clock and 9 o'clock locations on the ring that are different from the first weight portions so that the center of gravity coincides with the rotation axis, but the moment of inertia about a second axis through the 12 o'clock and 6 o'clock locations is different from the moment of inertia about a first axis through the 3 o'clock and 9 o'clock locations, so that the moment of inertia of the handheld pointing device about a longitudinal axis can be adjusted by either aligning the first axis of the weight unit with the longitudinal axis of the handheld pointing device or the second axis. Intermediate positions are of course also possible.

In an embodiment, the attachment member of the housing and the weight unit are configured to attach the weight unit to the housing such that the weight unit does not extend beyond an outer contour of the housing. This ensures that the presence of the weight unit does not interfere with the normal usage of the handheld pointing device compared to prior art handheld pointing devices.

In an embodiment, a center of gravity of the device without any weight unit attached to the housing is arranged on the rotation axis defined by the attachment member of the housing. This means that weight units of type A and type C can be designed with the center of gravity of the weight unit also being arranged on the rotation axis so that attaching the type A or type C weight unit to the housing does not affect or minimally affects the center of gravity and can thus be fully used for adjusting the weight and moment of inertia, respectively.

The invention according to the first aspect also relates to a weight unit for a handheld pointing device according to the first aspect of the invention, wherein the weight unit includes a substantially circular or ring-shaped attachment member, and wherein the weight unit has a weight distribution such that a center of gravity of the weight unit is located at a non-zero distance from a rotation axis of the weight unit and/or such that a moment of inertia of the weight unit about a first axis perpendicular to and through the rotation axis of the weight unit is different from a moment of inertia of the weight unit about a second axis perpendicular to and through the rotation axis.

The weight unit may comprise one or more of the earlier described features, so that these features will not be repeated here.

According to a second aspect of the invention, there is provided a combination of a computer keyboard and an extension unit for providing user input to a computing device, e.g. a computer, wherein the keyboard comprises: - a housing; - buttons and/or keys held by the housing; - an electronic module accommodated inside the housing to convert engagement with a button or key into coded form and to transmit the coded form to the computing device as user input, wherein the extension unit comprises: - a housing; - a button and/or key held by the housing; - an electronic module accommodated inside the housing to convert engagement with a button or key into coded form and to transmit the coded form to the electronic module of the keyboard for further transmittal to the computing device as user input, and wherein the keyboard and the extension unit are configured to releasably attach the housing of the extension unit to the housing of the keyboard at a plurality of different locations.

An advantage of the combination according to the second aspect of the invention is that the extension unit is attached to the housing of the keyboard and thus the extension unit after being attached to the keyboard forms an integral part thereof and the combination can be handled as a single unit during for instance gaming. The plurality of different locations to attach the extension unit allows to find an optimal location for a user or specific game.

In an embodiment, the housing of the keyboard includes electric connectors at the plurality of different locations to mate with a corresponding electric connector provided on the housing of the extension unit. The electric connectors on the keyboard may be of the female type and the electric connector on the extension unit may be of the male type, but the other way around or other electric connectors such as pogo pins may also be used.

In an embodiment, the housing of the keyboard includes a permanent magnet or ferromagnetic material associated with each location, wherein the housing of the extension unit includes a permanent magnet or ferromagnetic material to cooperate with the permanent magnet or ferromagnetic material at a location to attach the extension unit to the keyboard using magnetic forces.

In an embodiment, the housing of the extension unit includes a T-, L- or U-shape configured to be arranged on or around an edge of the housing of the keyboard.

In an embodiment, the electric connector and/or the permanent magnet or ferromagnetic material (if present) are arranged at a bottom of the U-shape or form a leg of the T-, L- or U-shape.

In an embodiment, the U-shape is configured to be clamped around the edge of the housing of the keyboard. The clamping engagement may be combined with the magnetic attachment described above. The magnetic attachment may then be used to align the extension unit with the keyboard to easily find the correct attachment location and the clamping engagement provided additional resistance against unwanted release of the extension unit.

In an embodiment, the electric module of the extension unit and the electric module of the keyboard are configured to wirelessly communicate with each other, e.g. using Bluetooth, WiFi, radio waves, infrared, etc.

In an embodiment, the keyboard includes a left side and a right side opposite the left side, wherein the extension unit includes a left side and a right side opposite the left side, and wherein the extension unit and keyboard are configured to allow attachment of the left side of the extension unit to the right side of the keyboard and to allow attachment of the right side of the extension unit to the left side of the keyboard.

In an embodiment, the extension unit includes an attachment device at the right side of the extension unit and an attachment device at the left side of the extension unit, wherein each attachment device is moveable between an operational position in which the extension unit can be attached to the keyboard using the attachment device and a retracted position in which the attachment device is prevented from engaging with the keyboard. In an embodiment, an attachment device does not extend beyond the housing of the extension unit in the retracted position.

In an embodiment, the attachment device at the right side is coupled to the attachment device at the left side so that an operational position of the attachment device at the right side corresponds to the retracted position of the attachment device at the left side and the operational position of the attachment device at the left side corresponds to the retracted position of the attachment device at the right side. In an embodiment, the coupled attachment devices also have an intermediate position in which both attachment devices are prevented from engaging with the keyboard, and in which preferably the attachment devices both do not extend beyond the housing of the extension unit. In an embodiment, the extension unit is a numeric keypad, a multimedia control unit, and/or a display unit.

In an embodiment, the plurality of locations to attach the extension unit to the keyboard are located at a top and/or bottom side of the keyboard. The invention according to the second aspect of the invention also relates to an extension unit for a keyboard, comprising: - a housing; - a button and/or key held by the housing;

- an electronic module accommodated inside the housing to convert engagement with a button or key into coded form and to transmit the coded form to the electronic module of the keyboard for further transmittal to the computing device as user input, wherein the keyboard and the extension unit are configured to releasably attach the housing of the extension unit to the housing of the keyboard at a plurality of different locations, wherein the housing of the extension unit preferably includes a permanent magnet or ferromagnetic material to cooperate with a permanent magnet or ferromagnetic material onthe keyboard to attach the extension unit to the keyboard using magnetic forces, wherein the housing of the extension unit preferably includes a T-, L- or U-shape configured to be arranged on or around an edge of the keyboard, and wherein preferably, in case a U-shape is applied, the U-shape is configured to be clamped around the edge of the housing of the keyboard.

The invention according to the second aspect of the invention further relates to an extension unit for a keyboard, comprising: - a housing; - a button and/or key held by the housing; - an electronic module accommodated inside the housing to convert engagement with a button or key into coded form and to transmit the coded form to the electronic module of the keyboard for further transmittal to the computing device as user input, wherein the keyboard and the extension unit are configured to releasably attach the housing of the extension unit to the housing of the keyboard at a plurality of different locations, wherein the extension unit includes a left side and a right side opposite the left side, and wherein the extension unit is configured to allow attachment of the left side of the extension unit to a right side of the keyboard and to allow attachment of the right side of the extension unit to a left side of the keyboard.

In an embodiment, the extension unit includes an attachment device at the right side of the extension unit and an attachment device at the left side of the extension unit, wherein each attachment device is moveable between an operational position in which the extension unit can be attached to the keyboard using the attachment device and a retracted position in which the attachment device is prevented from engaging with the keyboard.

In an embodiment, an attachment device does not extend beyond the housing of the extension unit in the retracted position.

In an embodiment, the attachment device at the right side is coupled to the attachment device at the left side so that an operational position of the attachment device at the right side corresponds to the retracted position of the attachment device at the left side and the operational position of the attachment device at the left side corresponds to the retracted position of the attachment device at the right side.

In an embodiment, the coupled attachment devices also have an intermediate position in which both attachment devices are prevented from engaging with the keyboard, and in which preferably the attachment devices both do not extend beyond the housing of the extension unit.

In an embodiment, the extension unit is a numeric keypad, a multimedia control unit and/or a display unit.

According to a third aspect of the invention, there is provided a combination of an input device for a computing device and a set of support elements, wherein the set of support elements includes at least two support elements, wherein the combination includes fasteners to fasten any number of support elements of the set of support elements to the input device, wherein the support elements are fastenable to the input device at a location on the input device to set a tilt angle of the input device, and wherein the set of support elements is configured such that a single support element can be fastened to the input device and such that a plurality of support elements can be fastened to the input device as a stack of support elements thereby allowing to set different tilt angles of the input device. In an embodiment, the input device is a keyboard or an extension unit for a keyboard, e.g. as described above in relation to the second aspect of the invention. In an embodiment, the set of support elements comprises a support element of type “a” which is configured to engage with a support surface, e.g. a table surface.

In an embodiment, the set of support elements comprises at least one support element of type “b” configured to be arranged in the stack of support elements between the input device and the support element of type “a”.

In an embodiment, the fasteners include a permanent magnet. However, other fasteners, such as snap-fit connectors, Velcro, a bayonet connection or a bolt.

In an embodiment, the set of support elements is a first set of support elements and the fasteners are first fasteners, wherein the combination further includes a second set of support elements, wherein the second set of support elements includes at least two support elements, wherein the combination includes second fasteners to fasten any number of support elements of the second set of support elements to the input device, wherein the support elements of the second set of support elements are fastenable to the input device at a location on the input device to set a tilt angle of the input device, and wherein the second set of support elements is configured such that a single support element can be fastened to the input device and such that a plurality of support elements can be fastened to the input device as a stack of support elements thereby allowing to set different tilt angles of the input device using the first and second set of support elements. In an embodiment, the keyboard includes an attachment location per set of support elements.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in a non-limiting way with reference to the accompanying drawings in which like parts are indicated by like reference symbols, and in which: Fig. 1A schematically depicts a bottom view of a handheld pointing device according to a first aspect of the invention; Fig. 1B schematically depicts a perspective bottom view of the handheld pointing device of Fig. 1A; Fig. 2A schematically depicts a perspective view of a type A weight unit for the handheld pointing device of Fig. 1A; Fig. 2B schematically depicts a bottom view of the type A weight unit of Fig. 2A; Fig. 2C schematically depicts a side view of the type A weight unit of Fig. 2A; Fig. 3A schematically depicts a perspective view of a type B weight unit for the handheld pointing device of Fig. 1A; Fig.3B schematically depicts a bottom view of the type B weight unit of Fig. 3A; Fig. 3C schematically depicts a side view of the type B weight unit of Fig. 3A; Fig. 4A schematically depicts a perspective view of a type A or C weight unit for the handheld pointing device of Fig. 1A; Fig. 4B schematically depicts a bottom view of the type A or C weight unit of Fig. 4A; Fig. 4C schematically depicts a side view of the type A or C weight unit of Fig. 4A; Fig. 5 schematically depicts a bottom view of the handheld pointing device of Fig. 1A with the type B weight unit of Fig. 3A in a different angular orientation; Fig. 6A schematically depicts a bottom view of a recess of the housing of a first aspect handheld pointing device according to another embodiment of the invention; Fig. 6B schematically depicts a bottom view of a weight unit suitable for the embodiment of the recess depicted in Fig. 64; Fig. 6C schematically depicts a bottom and side view of another weight unit suitable for the embodiment of the recess depicted in Fig. 6A;

Fig. 7A schematically depicts a bottom and cross-sectional view of a recess of the housing of a first aspect handheld pointing device according to a further embodiment of the invention; Fig. 7B schematically depicts a top and cross-sectional view of a weight unit suitable for the embodiment of the recess depicted in Fig. 74; Fig. 7C schematically depicts a top view of another weight unit suitable for the embodiment of the recess depicted in Fig. 7A; Fig. 8A schematically depicts an attachment member of the housing of a first aspect handheld pointing device according to yet another embodiment of the invention; Fig. 8B schematically depicts a top view of a weight unit suitable for the embodiment of the attachment member depicted in Fig. 8A; Fig. 9 schematically depicts a top view of an extension unit according to a second aspect of the invention; Fig. 10 schematically depicts a bottom view of the extension unit of Fig. 9; Fig. 11 schematically depicts a side view of the extension unit of Fig. 9; Fig. 12 schematically depicts a bottom view of the extension unit of Fig. 9 with the left attachment device in the operational position; Fig. 13 schematically depicts a bottom view of the extension unit of Fig. 9 with the right attachment device in the operational position; Fig. 14 schematically depicts a perspective top view of a combination of a keyboard and the extension unit of Fig. 9 with the left side of the extension unit attached to the right side of the keyboard, Fig. 15 schematically depicts a perspective bottom view of the combination of Fig.

14; Fig. 16 schematically depicts a perspective bottom view of the combination of Fig. 14, but now with the right side of the extension unit being attached to the left side of the keyboard; Fig. 17 schematically depicts a top view of an extension unit according to another embodiment of the second aspect of the invention; Fig. 18 schematically depicts a side view of the extension unit of Fig. 17; Fig. 19 schematically depicts a front view of the extension unit of Fig. 17;

Fig. 20 schematically depicts a bottom view of the extension unit of Fig. 17; Fig. 21 schematically depicts a perspective top view of a combination of a keyboard and the extension unit of Fig. 17; Fig. 22 schematically depicts a perspective top view of the combination of Fig. 21 with the extension unit attached at another location; Fig. 23 schematically depicts a detailed view of an attachment location on a keyboard suitable to connect the extension unit of Fig. 9 or the extension unit of Fig. 17; Fig. 24 schematically depicts an exploded perspective view of an embodiment of a combination of a keyboard and two sets of support elements according to a third aspect of the invention; Fig. 25 schematically depicts a side view of the combination of Fig. 24 at a first tilt angle of the keyboard; Fig. 26 schematically depicts a side view of the combination of Fig. 24 at a second tilt angle of the keyboard; and Fig. 27 schematically depicts a side view of the combination of Fig. 24 at a third tilt angle of the keyboard.

DETAILED DESCRIPTION OF THE INVENTION Figs. 1A and 1B schematically depict a handheld pointing device 100 according to a first aspect of the invention. Fig. 1A depicts a bottom view while Fig. 1B depicts a perspective bottom view also showing one of the sides of the handheld pointing device 100. In Figs. 1A and 1B, the handheld pointing device 100 is embodied as a computer mouse configured to translate two-dimensional motion of the device 100 relative to a surface into motion of a pointer on a display of a computer. From this point forward, reference will be made to computer mouse 100 or mouse 100, but it will be clear for a skilled person that these terms may be exchanged by the more general term handheld pointing device as used throughout this specification.

The mouse 100 includes a housing 101 with a bottom surface 102, a side surface 103 extending upwards from the bottom surface 102, and a top surface {not shown) opposite the bottom surface 102.

The mouse 100 further includes an electronic module 104 as is known in the art, which electronic module 104 is accommodated inside the housing 101 and is configured to convert a position, orientation and/or displacement of the housing 101 into coded form and to transmit the coded form as user input to the computer, in this case using a cable 110 (which is only partially depicted).

The mouse 100 further includes one or more buttons 106, 107, 108 in the side surface 103 allowing additional user input to be provided to the computer via the mouse 100. Not shown, but a right-click button and a left-click button and possibly a scrol! wheel may be provided at the top surface of the mouse 100 to allow additional user input to be provided to the computer via the mouse 100 as is known in the art.

The electronic module 104 includes a sensor 105, e.g. an optical sensor, to interact with a surface to detect a displacement or motion of the device relative to the surface. The buttons 106-108 in the side surface and/or the buttons on the top surface may be considered to be part of the electronic module, but may alternatively be considered separate of the electronic module and part of the housing depending on the specific configuration and design. The sensor 105, and possibly the buttons, are the only visible parts of the electronic module 104.

As is known in the art, the mouse 100 is connected to the computer via a cable 110, which allows to use the cable 110 also for providing power to the electronic module 104. However, it may well be possible that the handheld pointing device is wireless and communication with the computer is established using wireless techniques, e.g. Bluetooth. Power may then be provided using one or more batteries accommodated inside the housing 101 as well.

The bottom surface 102 is provided with two cushion elements 109 allowing to smoothly move the bottom surface 102 and thus the mouse 100 over most of the widely used top surfaces of tables and/or mouse mats.

The housing 101, in this case the bottom surface 102 of the housing 101, is provided with a substantially ring-shaped recess 111 serving as an attachment member of the housing 101 for attaching a weight unit 120 to the housing 101. The recess 111 is substantially ring-shaped as it also contains an extension 111a to the ring-shaped recess 111 allowing to receive a fingertip for engagement with a side surface of the weight unit 120 allowing to relatively easily remove the weight unit 120 from the recess 111. In this exemplary embodiment, the weight unit 120 is completely received inside the recess 111, so that the entire weight unit 120 forms an attachment member engaging with the side walls and/or the bottom wall of the recess 111 as attachment member of the housing 101. As a result thereof, the weight unit 120 and thus its attachment member are also ring-shaped.

The side walls of the recess 111 and/or, but preferably or, the side walls of the weight unit 120 may be provided with elastically deformable material such as rubber so that the engagement between the recess 111 and the weight unit 120 is mainly based on friction.

Alternatively, the bottom wall of the recess 111 is provided with a permanent magnet and the weight unit 120 comprises ferromagnetic material or another permanent magnet so that the engagement between the recess 111 and the weight unit 120 is mainly based on magnetic forces.

Removing the weight unit 120 from the recess 111 then requires either the overcoming of the friction or the overcoming of the magnetic forces by applying a sufficiently large force to the weight unit using the extension 111a.

In an embodiment, the weight unit 120 can be snapped into the recess 111 using one or more hooks provided either on the weight unit or in the recess.

The recess 111 defines a rotation axis 112 coinciding with the sensor 105 and extending perpendicular to the plane of drawing in Fig. 1A, i.e. extending perpendicular to the bottom surface 102.

The weight unit 120 has a weight distribution such that a center of gravity of the weight unit 120 is located at a non-zero distance from the rotation axis 112 and such that a moment of inertia of the weight unit 120 about a first axis 121 perpendicular to and through the rotation axis 112 of the weight unit 120 is different from a moment of inertia of the weight unit 120 about a second axis 122 perpendicular to and through the rotation axis 112 of the weight unit 120. Different types of weight units will be further explained below by reference to the Figs. 2A — AC. The housing 101 and the weight unit 120 are configured to removably attach the attachment member of the weight unit 120, i.e. the weight unit 120 itself in this embodiment, to the attachment member, i.e. the recess 111 in this embodiment, of the housing 101 in multiple angular orientations about the rotation axis 112. An example of such another angular orientation is shown in Fig. 5, in which a bottom view of the same mouse 100 is depicted, but in which the weight unit 120 has rotated by 180 degrees compared to the situation depicted in Fig. 1A. In this embodiment, the rotation has adjusted both the center of gravity of the mouse 100 as well as the moment of inertia of the mouse 100. The adjustments to the center of gravity and/or the moment of inertia may be optimal for a person playing games with the mouse 100 or using the mouse 100 for other heavy-duty activities in which speed and/or accuracy may be required.

The recess 111 is sufficiently deep to accommodate the weight unit 120 such that the weight unit 120 does not extend beyond the bottom surface 102. The recess 111 may be so deep that two, three or even four weight units may be received inside the recess 111, preferably with none of the weight units extending beyond the bottom surface 102.

Weight units 120 that can be used in combination with the housing 101 of the mouse 100 will be described in more detail below by reference to the Figs. 2A —4C.

Figs. 2A, 2B and 2C depict a type A weight unit 120a configured to be received in the recess 111 of the housing 101 of the mouse 100 shown in Figs. 1A and 1B. Fig. 2A depicts a perspective view, Fig. 2B depicts a bottom view and Fig. 2C depicts a side view.

Atype A weight unit 120a has a uniform weight distribution so that the center of gravity COG of the weight unit 120a is arranged on the rotation axis 112 of the weight unit when received inside the recess 111. The uniform weight distribution in combination with the ring-shape of the weight unit 120a causes the moment of inertia about a first axis 121 to be equal to the moment of inertia about a second axis 122. As a result thereof, especially when the center of gravity of the mouse 100 without the weight unit 120a is arranged on the rotation axis 112 defined by the recess 111, attaching the type A weight unit 120a of Figs. 2A-2C will result in adding weight and changing the moment of inertia to the mouse 100 independent of the angular rotation of the weight unit 120a about the rotation axis 112, so that adjustment of the weight and moment of inertia after attaching the weight unit to the housing by changing the angular orientation is not possible. Attaching the weight unit 120a may result in adjusting the center of gravity when the center of gravity of the device is not arranged on the rotation axis 112, but again after attaching the weight unit 120a to the housing 101 it is no longer possible to adjust the center of gravity of the mouse 100 by changing the angular orientation of the weight unit 120a. Hence, a type A weight unit 120a according to Figs. 2A-2C will mainly be used to add weight to the mouse 100. Figs. 3A-3C depict a type B weight unit 120b configured to be received in the recess 111 of the housing 101 of the mouse 100 shown in Figs. 1A and 1B. Fig. 3A depicts a perspective view, Fig. 3B depicts a bottom view and Fig. 3C depicts a side view. A type B weight unit 120b has a weight distribution that is non-uniform, i.e. asymmetric about the rotation axis 112 due to the provision of three recesses or through-openings 123a, 123b, 123c that are not evenly distributed about the rotation axis 112, so that the center of gravity COG of the weight unit 120b is at a non-zero distance from the rotation axis 112 as can be clearly seen in the bottom view of Fig. 3B. As a result thereof the moment of inertia about the first axis 121 is different from the moment of inertia about the second axis 122. Hence, by attaching the weight unit 120b to the housing 101 of the mouse 100, the weight, center of gravity and moment of inertia will be affected. After attaching the weight unit 120b, the center of gravity can be adjusted by changing the angular orientation causing the center of gravity COG of the weight unit 120b to change position. Along with the center of gravity, the moment of inertia will also change when changing the angular orientation.

The type B weight unit 120b is depicted in the Figs. 1A, 1B and 5 as an example of weight unit 120. As earlier described, the weight unit 120 in Figs. 1A and 1B has an angular orientation rotated 180 degrees relative to the angular orientation of the weight unit 120 in Fig. 5 thereby changing the center of gravity and the moment of inertia. However, it is noted that the moment of inertia of the mouse 100 is only changed about a rotation axis parallel to the first rotation axis 121 shown in Fig. 1A. Figs. 4A, 4B and 4C depict a weight unit 120c that can be embodied as a type A weight unit or a type C weight unit as described in more detail below, and that is configured to be received in the recess 111 of the housing 101 of the mouse 100 shown in Figs. 1A and 1B. Fig. 4A depicts a perspective view, Fig. 4B depicts a bottom view and Fig. 4C depicts a side view. The weight unit 120c has four recesses or through-openings 123a-123d that are evenly distributed about the ring-shaped weight unit 120c. Recesses or through-openings 123a and 123b form a first pair of recesses or through-openings and recesses or through- openings 123c and 123d form a second pair of recesses or through-openings. When all recesses or through-openings 123a-123c are identical in shape, the weight unit 120c forms a type A weight unit, but when the first pair of recesses or through-openings 1234, 123b is different from the second pair of recesses or through-openings 123c, 123d, the center of gravity COG is stil! arranged on the rotation axis 112, but the moment of inertia about the first axis 121 is different from the moment of inertia about the second axis 122.

This is considered to be a type C weight unit, which affects the weight and the moment of inertia, and possibly the center of gravity of the mouse 100 when attached to the housing 101, but after attaching is able to adjust only the moment of inertia by changing the angular orientation of the weigh unit 120c about the rotation axis 112.

Recess or through-opening 123d in Fig. 4B is at a 12 o'clock location on the ring, recess or through-opening 123b is at a 3 o’clock location on the ring, recess or through-opening 123c is at a 6 o'clock location on the ring, and recess or through-opening 123aisata 9 o'clock location.

As can be seen in the Figs. 2C, 3C and 4C, the thickness of the weight unit can be relatively small. When the recess 111 is sufficiently deep, two or more, e.g. three or four, weight units can be received simultaneously in the recess 111. Hence, the type A weight unit can be used to mainly adjust the weight, the type B weight unit can be used to mainly adjust the center of gravity, and the type C weight unit can be used to mainly adjust the moment of inertia. However, when moment of inertia is not that important, only type A and type B weight units can be used, or when center of gravity is already optimal, only type A and type C weight units can be used.

A sufficiently deep recess 111 may be used to keep the one or more weight units within a contour of the housing to prevent any interference during use. The cushion elements 109 may allow the weight units to extend a little bit beyond the contour without risking interference, especially when the cushion elements are relatively thick to provide clearance.

However, as type B and type C weight units can also be used to adjust the weight, it is also conceivable that only type B and/or type C weight units are used.

It is noted that the embodiments shown in Figs. 1A —5 are only one example and that many variants exist. To show some of the variants, reference is made to the Figs. 6A-8B, which will be described below in more detail.

Fig. 6A schematically depicts a recess 111 of a housing 101, which recess 111 has a circular shape instead of a ring shape. The circular shape defines a rotation axis 112 for a weight unit received inside the recess 111.

Fig. 6B schematically depicts a weight unit 120 which is configured to be received inside the recess 111 of the housing 101 such that the weight unit can be rotated about the rotation axis 112. The weight unit 120 is also circular shaped, but not a complete circle, but only a circle segment. As a result thereof, the center of gravity COG is at a distance from the rotation axis 112 and the moment of inertia about the first axis 121 is different from the moment of inertia about the second axis 122. The weight unit of Fig. 6B is therefore of type B. Fig. 6C schematically depicts another weight unit 120 which is configured to be received inside the recess 111 of the housing 101 such that the weight unit can be rotated about the rotation axis 112. The weight unit 120 is also circular shaped, but as can be seen in the cross-sectional view along the second axis 122, the thickness of the weight unit 120 at one side is larger than the thickness of the weight unit 120 at the opposite side. As a result thereof, the center of gravity COG is at a distance from the rotation axis 112 and the moment of inertia about the first axis 121 is different from the moment of inertia about the second axis 122. The weight unit of Fig. 6C is therefore also of type B. Fig. 7A schematically depicts a recess 111 of a housing 101, which recess 111 has a ring shape and comprises a receiving recess 111a for receiving a main body of a weight unit and an attachment member 111b embodied as a recess at the bottom of the receiving recess 1114. Both the receiving recess 111a and the attachment member 111b are ring- shaped. The ring-shaped attachment member 111b defines a rotation axis 112 for a weight unit received inside the recess 111. Fig. 7B schematically depicts a top view and a cross-sectional view of a weight unit 120 which is configured to be received inside the recess 111 of the housing 101. The weight unit 120 therefore comprises a main body 120.1 to be received in the receiving recess 111a of the recess 111 and an attachment member 120.2 to be attached to the attachment member 111b of the recess 111. In this embodiment, the attachment member 120.2 is ring-shaped and thus complementary to the ring shape of the attachment member 111b of the recess 111.

Fig. 7C schematically depicts a top view of a weight unit 120 which is configured to be received inside the recess 111 of the housing 101. The weight unit 120 therefore comprises a main body 120.1 to be received in the receiving recess 111a of the recess 111 and an attachment member to be attached to the attachment member 111b of the recess 111. In this embodiment, the attachment member includes ring segments 120.2 to be received in the attachment member 111b of the housing 101. The ring segments 120.2 do not form a complete ring shape, but are arranged in a circular manner.

Fig. 8A schematically depicts a bottom view of an attachment member 111 of a housing

101. Fig. 8B schematically depicts a top view of a weight unit 120 to be attached to the housing 101. The weight unit 120 includes a main body 120.1 having an octagon shape and an attachment member including a pair of snap-fit connectors 120.2. The attachment member 111 of the housing 101 includes four pairs of corresponding snap-fit connectors 111b arranged in a circular manner. The pair of snap-fit connectors 120.2 can interlock with a pair of snap-fit connectors 111b on the housing 101 to attach the weight unit 120 to the housing 101. Due to the circular arrangement of both the snap-fit connectors 111b and the snap-fit connectors 120.2, the attachment members define a rotation axis 112 allowing to attach the weight unit 120 in different discrete angular positions about the rotation axis 112, in this case 8 different discrete angular positions.

This is in contrast to the possibility of the other shown embodiments in the figures to attach the weight unit to the housing in an infinite number of different angular positions. Changing angular position may be carried out by overcoming friction or magnetic forces between the recess 111 and the weight unit 120 and rotating the weight unit about the rotation axis 112. It is also possible to take the weight unit 120 out of the recess and put the weight unit 120 back in a different angular orientation.

Although not shown in the variants, the main bodies of the weight units may include extensions compared to the already shown shapes, for instance to increase the distance between center of gravity and rotation axis. For instance, the type B weight unit shown in Fig. 3B may have an extension at the 12 o'clock location to further increase the distance between the center of gravity COG and rotation axis 112. Figs. 9-13 schematically depict an extension unit 200 according to an embodiment of the second aspect of the invention. Fig. 9 depicts a top view, Fig. 10 depicts a bottom view, Fig. 11 depicts a side view, and Figs. 12 and 13 depict a bottom view of different configurations of the extension unit 200. The extension unit 200 comprises a housing 201 and a plurality of keys 202 of which only a limited number of keys are indicated using reference numeral 202. The extension unit 200 in this embodiment is a numerical keypad. Inside the extension unit 200, an electronic module is accommodated to convert engagement of a user with a key 202 into coded format and to transmit the coded form to a keyboard to be transmitted to a computing device, e.g. a computer, as user input. As the electronic module is accommodated inside the housing 201, the only visible part of the electronic module in this embodiment are two male electric connectors 203 as shown in Figs. 11 to 13 that are configured to allow communication between the electronic module of the extension unit and an electronic module of a keyboard. The extension device 200 includes two attachment devices, namely an attachment device 210 at a right side of the extension device 200 and an attachment device 211 at a left side of the extension device 200, where left and right are to be considered in top view of the extension unit 200. Hence, as Figs. 12 and 13 depict a bottom view, the right-side attachment device 210 is shown on the left and the left side attachment device 211 is shown on the right.

In this embodiment, the right-side attachment device 210 includes a male electric connector 203, two alignment pins 204 and an attachment member 205. The left side attachment device 211 similarly includes a male electric connector 203, two alignment pins 204 and an attachment member 205. The right-side attachment device 210 and the left side attachment device 211 are connected to each other, so that they are moveable as a single unit.

Connected to the single unit is a knob 206 which is slidingly received in a slot 207 in a bottom of the housing 201. The knob 206 allows to manually move the single unit between three distinct positions as explained below.

Other manipulation members such as a rib, a larger surface, possibly embodied as rough textured surface, or a pin, etc. are also envisaged as alternative or addition to the knob 206. In a first position, also referred to as the intermediate position, the knob 206 is positioned halfway the slot 207. The first position is clearly depicted in Figs. 9 and 10. The intermediate position is characterized in that both the right-side attachment device 210 and the left side attachment device 211 do not extend outside the housing 201 and thus cannot be used to connect the extension unit to a keyboard.

This may be beneficial for transport and storage as the connectors and pins are protected inside the housing 201 from being damaged.

Ina second position, also referred to as the right attachment position, the knob 206 is positioned at the left side attachment device side of the slot 207 as clearly depicted in Fig. 12 and in which the left side attachment device 211 extends from the housing of the extension device to attach the left side of the extension unit 200 to the right-side of a keyboard.

In the second position, the left side attachment device 211 is considered to be in an operational position while the right-side attachment device 210 is considered to be in a retracted position.

In a third position, also referred to as the left attachment position, the knob 206 is positioned at the right-side attachment device side of the slot 207 as clearly depicted in Fig. 13 and in which the right-side attachment device 210 extends from the housing of the extension device to attach the right-side of the extension unit 200 to the left side of a keyboard.

In the third position, the left side attachment device 211 is considered to be in a retracted position while the right-side attachment device 210 is considered to be in an operational position.

Figs. 14 and 15 schematically depict a combination of a keyboard 250 and the extension unit 200 connected to a right side of the keyboard and thus with the attachment devices 210 and 2011 in the right attachment position. Fig. 14 depicts a perspective top view and Fig. 15 depicts a perspective bottom view.

The keyboard 250 includes a housing 251, a plurality of keys 252 {of which only a limited number of keys are denoted using reference numeral 252), and an electronic module accommodated by the housing 251 and configured to convert engagement with a key 252 into coded form and to transmit the coded form to a computing device, e.g. a computer, as user input. The keyboard 250 may be connected to the computer via a wire or wirelessly as is known in the art.

For the keyboard, references to the left and right side of the keyboard should be interpreted in the top view of the keyboard. Hence, Fig. 15 shows the left side of the keyboard 250 on the right side of the drawing. The left side of the keyboard 250 is provided with a female electric connector 253 to cooperate with the male electric connector 203 of an extension unit, two alignment holes 254 to receive the alignment pins 204 of an extension unit, and an attachment member 255 to mate with the attachment member 205 of an extension unit. The same components are provided on the right side of the keyboard 250 to attach the extension unit 200 to the keyboard 250.

Of course the male and female connectors could be interchanged as well or replaced by pogo pins or other electric connectors. It may be envisaged that the keyboard 250 includes one or more rails in or along the edge to engage with corresponding electric connectors of the extension unit. This has the advantage that no distinct attachment locations are provided but the extension unit is able to electrically connect at any location along the rail. The same advantage may be obtained using a wireless connection method. The same principle may be obtained by providing a magnetic rail or a rail of ferromagnetic material to attach the extension unit at any location along the rail.

Fig. 16 depicts a perspective bottom view of the combination of Figs. 14 and 15, but now with the extension unit 200 being connected to the left side of the keyboard 250 and thus the attachment devices in the left attachment position.

The alignment pins 204 on the extension unit and the alignment holes 254 on the keyboard allow the male and female connectors to easily mate with each other and also prevents the application of a too large load to the electric connectors which could lead to damage and/or a loss in communication. However, it is also envisaged that no electric connectors are used and that communication between the electronic module of the extension unit and the electronic module of the keyboard is wireless.

The alignment pins 204 may be frictionally engage with the alignment holes 254, but alternatively, the alignment pins 204 and alignment holes 254 may include magnetic and/or magnetizable material to apply magnetic forces between the keyboard and the extension unit.

The attachment members 205 and 255 may be connected to each other using magnetic forces as well.

Figs. 17-20 schematically depict an extension unit 200 according to another embodiment of the second aspect of the invention. Fig. 17 depicts a top view, Fig. 18 depicts a side view, Fig. 19 depicts a front view and Fig. 20 depicts a bottom view.

The extension unit 200 includes a housing 201 and a plurality of knobs 2023, 202b held by the housing 201, wherein the knobs 202a can be pressed and the knob 202b may be turned and/or pressed.

The housing 201 accommodates an electronic module configured to convert engagement with a knob, alternatively referred to as a key, into coded form and transmit the coded form to an electronic module of a keyboard for further transmittal to a computing device as user input.

The housing 201 includes a U-shaped recess 201a as can be best seen in Fig. 18, with a bottom of the U-shape containing an attachment member 205 configured to engage with an edge of a keyboard for preferably a clamping engagement. One leg of the U-shape supports the knobs 202a, 202b, while the other leg of the U-shape supports a male electric connector 203 and magnetic attachment members 204 for cooperation with a female electric connector and magnetic attachment members on the keyboard, respectively.

Figs. 21 and 22 schematically depict a combination of a keyboard 250 and the extension unit 200 of Figs. 17-20. The keyboard includes a housing 251, a plurality of keys 252 (of which only a limited number of keys are denoted using reference numeral 252), and an electronic module accommodated by the housing 251 and configured to convert engagement with a key 252 into coded form and to transmit the coded form to a computing device, e.g. a computer, as user input. The keyboard 250 may be connected to the computer via a wire or wirelessly as is known in the art.

The keyboard 252 contains multiple locations including a female electric connector and magnetic attachment members for cooperation with the extension unit to allow the extension unit to be attached at different locations to the keyboard. Fig. 23 depicts a detail of such a location clearly showing a female electric connector 253 and the magnetic attachment members 254. Also shown is an edge 251a of the housing of the keyboard around which the U-shaped recess of the housing of the extension unit can be arranged. The edge 251a of the housing includes a recess 251b allowing to receive the attachment member 205 arranged at the bottom of the U-shaped recess of the extension unit 200 thereby providing a clamping engagement between the extension unit 200 and the keyboard.

Fig. 21 shows the extension unit attached near an upper right corner of the keyboard while Fig. 22 shows the extension unit attached near an upper left corner of the keyboard. However, it may well be possible to connect the extension unit to the left or right side of the keyboard as well. In fact, there may be an embodiment in which the extension unit can be connected to the upper side and/or the right side and/or the left side and/or the bottom side, e.g. along the entire perimeter of the keyboard. In an embodiment, the right and left side of the keyboard and the extension units described herein may be configured such that both the extension unit of Fig. 17 and the extension unit of Fig. 9 can be attached to the same keyboard providing flexible extensions to the keyboard depending on the requirements of the task performed with the keyboard.

Fig. 24 to Fig. 27 schematically depict an embodiment of a combination of a keyboard 300 and two sets of support elements 301, 302 according to a third aspect of the invention. Fig. 24 depicts an exploded perspective view, while Figs. 25-27 depict side views with the keyboard at different tilt angles as will be explained below in more detail.

The keyboard 300 is an example of an input device. In this example, the combination includes two sets of support elements, wherein a first set of support elements is denoted using reference numeral 301 and a second set of support elements is denoted using reference numeral 302. Both sets of support elements have been depicted in exploded view to clearly indicate the different support elements.

Each set of support elements 301, 302 includes in this embodiment three support elements of which one support element is of a type “a” and the other two support elements are of a type “b”, which support elements are denoted using a reference numeral starting with the reference numeral of the corresponding set of support elements followed by the letter indicating their type, e.g. support element 302b is part of the second set of support elements and of type “pb”.

The keyboard 300 in this embodiment includes an attachment location 300.1, 300.2 per set of support elements 301, 302. The attachment locations 300.1, 300.2 are arranged at the bottom of the keyboard near the backside at the two corners. An advantage of the two attachment locations at a distance from each other is that they are able to provide a stable support for the keyboard. However, it is also possible to use a single set of support elements at a center of the back side in between the current attachment locations. The attachment locations 300.1, 300.2 are recognizable by a circular-shaped protrusion that is configured to mate with a corresponding recess in one of the support elements. However, other shapes of the protrusion and recess are also envisaged. Type “b” support elements in this embodiment are characterized by having a recess at one side to mate with a protrusion of another support element or the protrusion at the attachment location, and by having a protrusion at an opposite side to mate with a recess of another support element.

Type “a” support elements in this embodiment are characterized by having a recess at one side to mate with a protrusion of another support element or the protrusion at the attachment location, and by having an engagement surface at an opposite side to engage with a support surface such as a table top surface.

The recesses of the type “a” and type “b” support elements are preferably identical or at least similar to each other, and/or the protrusions of the type “b” support elements and the protrusion of the attachment location are preferably identical or at least similar to each other. An advantage thereof is that the support elements of a set of support elements can easily be stacked with minimal requirements on the number of and the order of the support elements.

The combination includes fasteners to fasten any number of support elements of each set of support elements to the keyboard 300. In this example, the fasteners include at least one permanent magnet per set of support elements. Permanent magnets have the advantage that fastening can be done quickly and easily. One of the following configurations of the fasteners may be used: A) a single permanent magnet in the protrusion at the attachment location and magnetizable material, e.g. ferromagnetic material, in all support elements;

B) a single permanent magnet in the type “a” support element and magnetizable material, e.g. ferromagnetic material, in the type “b” support elements and the protrusion at the attachment location; C) a permanent magnet in each support element and magnetizable material, e.g.

ferromagnetic material, in the protrusion of the attachment location and possibly in one or more support elements; or D} a permanent magnet in each support element and in the protrusion of the attachment location.

The set of support elements and the fasteners are configured to allow any number of support elements to be fastened to the keyboard 300 to set different tilt angles of the keyboard 300. In case of three support elements in a set of support element as in this embodiment, the fasteners preferably allow to fasten one, two of three support elements to the keyboard as will be explained below by reference to the Figs. 25-27.

Fig. 25 schematically depicts a side view of the combination of the keyboard 300 and the first set of support elements 301 with all support elements 301a, 301b forming a stack of three support elements and being fastened to the keyboard thereby setting a maximum tilt angle a of the keyboard 300.

Fig. 26 schematically depicts a side view of the combination of the keyboard 300 and the first set of support elements 301 with a support element 301a and a support element 301b forming a stack of two support elements and being fastened to the keyboard thereby setting an intermediate tilt angle a of the keyboard 300 that is smaller than the maximum tilt angle in Fig. 25.

Fig. 27 schematically depicts a side view of the combination of the keyboard 300 and the first set of support elements 301 with only support element 301a being fastened to the keyboard thereby setting a minimum tilt angle a of the keyboard 300 that is smaller than the intermediate tilt angle of Fig. 26.

A difference between adjacent tilt angles may be in the range 1-3 degrees, preferably in the range 1.5-2.5 degrees, e.g. 2 degrees. Although in this embodiment, permanent magnets are used, other type of fastening means may also be used, e.g. snap-fit connectors, Velcro, bayonet connection or a simple bolt. Although each set of support elements in this embodiment comprises three support elements, it is also possible to use two, four or five support elements in a set of support elements. Although in this embodiment, the number of support elements is equal to the number of tilt angles to be set, it is also possible in another embodiment, to use a set of support elements with two support elements, wherein one support element is thicker than the other support element, so that with two support elements, three different tilt angles can be set, namely, a first tilt angle defined by the thin support element, a second tilt angle defined by the thick support element, and a third tilt angle defined by the stack of both support elements. It is envisaged that this principle can be extended to a set of support elements with more than two support elements by having at least one support element with a different thickness than other support elements. In the embodiment of Figs. 24-27, always the type “a” support element engages with a support surface independent of the situation. This has the advantage that the type “a” support element can be specifically designed for engagement with the support surface, e.g. by including a foot, for instance a rubber foot, and that the other support elements do not need such a specifically designed foot. In this embodiment, the type “a” support element includes grooves on its outer surface to allow easy manual manipulation of this support element.

In this embodiment, the protrusions and recesses in the support element allow to align the support elements within a stack. Such alignment is not necessary per se and may also be obtained in different ways, e.g. when a bolt is used as fastener and the support elements have a bore to receive the bolt. It will be apparent to the skilled person that the second aspect of the invention may be combined with the third aspect of the invention. To illustrate this, feet 310 in Figs. 10 and may be embodied as a set of support elements according to the third aspect and an extension unit 200 similar to the extension unit 200 in Figs. 17-22 is depicted in Figs. 25-

27.

Claims (15)

CONCLUSIONS A handheld pointing device for providing user input to a computing device, comprising: a. a housing; b. an electronic module housed in the housing for converting position, orientation and/or displacement of the housing into coded form and for transmitting the coded form as user input to the computing device; and c. a weight unit having a connecting member, the housing comprising a connecting member for connecting the connecting member of the weight unit to the housing, the connecting members of the housing and the weight unit defining an axis of rotation for the weight unit, the weight unit having a weight distribution such that a center of gravity of the unit of weight is located at a non-zero distance from the axis of rotation and/or such that a moment of inertia of the unit of weight about a first axis perpendicular to the axis of rotation of the unit of weight is different from a moment of inertia of the unit of weight about a second axis perpendicular on the axis of rotation and different from the first axis, and wherein the housing and the weight unit are adapted to interchangeably connect the connector of the weight unit to the connector of the housing in at least three different angular orientations of the weight unit around d the rotation axis having a smallest angle between two extreme angular orientations spanning all intermediate angular orientations that is at least 135 degrees, preferably is at least 150 degrees, more preferably is at least 165 degrees, and most preferably is at least 180 degrees. The handheld pointing device of claim 1, wherein the weight unit connector and/or the housing connector is substantially circular or annular. The handheld pointing device according to claim 1 or 2, wherein the housing and the weight unit are arranged to connect the weight unit to the housing by means of the connector in at least four, preferably at least five, more preferably at least six and most preferably an infinite number of different angular orientations of the weight unit about the axis of rotation. The handheld pointing device according to any one of claims 1 to 3, wherein a coupling between the weight unit connector and the housing connector is based mainly on friction. The handheld pointing device of claim 4, wherein the weight unit is rotatable about the axis of rotation relative to the connector of the housing by overcoming the friction. The handheld pointing device according to any one of claims 1 to 5, wherein the entire weight unit forms the connector. The handheld pointing device according to any one of claims 1 to 6, wherein the connector of the housing includes a recess for receiving the connector of the weight unit. The handheld pointing device according to any one of claims 1 to 7, wherein the weight unit and the connector of the housing are both annular and arranged to have a sensor of the electronic module in the housing arranged to determine a position, orientation and /or measure, surround displacement of the housing relative to a reference. The handheld pointing device of any one of claims 1 to 8, wherein the housing connector is configured to connect at least two separate weight units. The handheld pointing device according to any one of claims 1 to 9, wherein the connector of the housing and the weight unit is adapted to connect the weight unit to the housing such that the weight unit does not extend beyond an outer contour of the housing. The handheld pointing device according to any one of claims 1 to 10, wherein a center of gravity of the device having no weight unit connected to the housing is located on the axis of rotation defined by the connector of the housing. A weight unit for the handheld pointing device according to any one of claims 1 to 11, wherein the weight unit has a substantially circular or annular connector, and wherein the weight unit has a weight distribution such that a center of gravity of the weight unit is on a non-zero distance from an axis of rotation of the unit of weight and/or such that a moment of inertia about a first axis perpendicular to and through the axis of rotation of the unit of weight is different from a moment of inertia of the unit of weight about a second axis perpendicular to and through the axis of rotation. 13. A combination of a computer keyboard and an expansion unit for providing user input to a computing device, the keyboard comprising: - a housing; - buttons and/or keys carried by the housing; - an electronic module housed in the housing to convert the actuation of a button or key into coded form and to transmit the coded form to the computing device as user input, the expansion unit comprising: - a housing; - a button and/or key carried by the housing; an electronic module housed in the housing to convert the actuation of a button or key into coded form and to transmit the coded form to the electronic module of the keyboard for further transmission to the computing device as user input, and wherein the keyboard and expansion unit are adapted to releasably connect the expansion unit housing to the keyboard housing at a plurality of different locations. 14. A keyboard expansion unit, comprising: - a housing; - a button and/or key carried by the housing; an electronic module housed in the housing to convert the actuation of a button or key into coded form and to transmit the coded form to the electronic module of the keyboard for further transmission to the computing device as user input, the keyboard being and the expansion unit is adapted to releasably connect the expansion unit housing to the keyboard housing at a plurality of different locations, the expansion unit housing preferably comprising a permanent magnet or ferromagnetic material to cooperate with a permanent magnet or ferromagnetic material on the keyboard for bonding the expansion unit to the keyboard by magnetic forces, the expansion unit housing preferably having a T, L or U shape adapted to be mounted on or around an edge of the keyboard, and where, in the case is a U-shape applied, the U-shape is arranged to be clamped around the edge of the keyboard housing. 15. A keyboard expansion unit, comprising: - a housing; - a button and/or key carried by the housing; an electronic module housed in the housing to convert the actuation of a button or key into coded form and to transmit the coded form to the electronic module of the keyboard for further transmission to the computing device as user input, the keyboard being and the expansion unit is arranged to releasably connect the expansion unit housing to the keyboard housing at a plurality of different locations, wherein the expansion unit includes a left side and a right side opposite the left side, and wherein the expansion unit is configured to allow a connection between the left side of the expansion unit and a right side of the keyboard and to allow a connection between the right side of the expansion unit and a left side of the keyboard.