The present invention relates to a user-interface device, comprising a plurality of indication elements for display of information and/or input of commands or data.
More in particular, the invention relates to a user-interface device that can be configured or reconfigured according to the need, namely, of the type in which indication elements can be variously positioned in the device, but in any case in such a way that they can be uniquely identified by an electronics to which the device itself is connected.
Known to the art are devices designed to guarantee reconfigurability of a keyboard or, in general, of a user-interface device.
For example, the document No. US 2004/0155868- to the introductory part of which the reader is referred also for a general discussion on reconfigurable user-interface devices—describes a device designed to render the keys of an interface system uniquely recognizable. With reference to
The document No. U.S. Pat. No. 6,891,528 describes a keyboard for disabled persons, in which each key 200 (see the annexed
As has been explained, the interface devices described in the aforesaid prior documents present non-negligible complications from the standpoint of the production process. The main aim of the present invention is to overcome the aforesaid drawbacks.
The aforesaid known interface devices cannot, moreover, be equipped with a system for back-lighting of the visual indications provided on the keys. Another aim of the invention is hence to solve said drawback, in a simple and economically advantageous way, guaranteeing that each visual indication of the user-interface device is effectively and uniformly lit up.
The invention will now be described with reference to the annexed drawings, which are provided purely by way of non-limiting example and in which:
Represented schematically in
In
The indication elements 3 are mounted in a repositionable way on the device 1, or they can be mounted in different positions on the device itself, according to the need. For said purpose, as will emerge clearly hereinafter, the elements 3 are provided with respective identification means, designed to co-operate with detection means provided in the device 1, said detection means being connected to the control system CS, which is pre-arranged for recognizing in a unique way the individual identity of the elements 3, irrespective of the position assigned thereto within the device 1.
In
In said
The upper wall 3a of the body 3, designed to remain exposed by the device 1, has a face provided externally with the visual indication 4. For said purpose, in the preferred embodiment of the invention, the outer face of the wall 3a is coated with a layer of paint 9a, preferably an optically non-transmissive paint, in which the indication 4 is made. The indication 4 can be, for example, obtained by laser ablation, chemical etching, or any other method adapted to remove partially, according to a desired pattern, the layer 9a, leaving the underlying material of the body 3, which has different colouring with respect to that of the paint of the layer 9a, exposed. Another possibility is to deposit the layer 9a in a selective way in order to coat the surface of the wall 3a except in the region of the pattern desired for the indication 4.
According to one characteristic of the invention, the face of at least one of the side walls 3b of the body 3 is coated at least in part by a layer of electrically conductive paint, designated by 10 and also referred to hereinafter as “conductive layer”. The paint that constitutes the layer 10 may, for example, be obtained by introducing a filler of metal particles into a polymeric base. In the example, the layer 10 coats a lower region of the external faces of the walls 3b, for a band that extends from the lower edge of the walls themselves up to a height at least equal to d1.
Superimposed on the conductive layer 10 is a layer of electrically insulating paint, designated by 9b and also referred to hereinafter as “insulating layer”. The layer 9b can substantially coat entirely the external face or faces of the walls 3b and can belong to the layer 9a deposited on the top wall 3a; in this case, deposition of the non-conductive paint is obtained substantially simultaneously on the external faces 3a and 3b, for example, by spraying or dipping.
According to another characteristic of the invention, the insulating layer 9b has one or more windows 11 in given positions, which enable local exposure of the underlying conductive layer 10, said windows 11 having a height at least equal to d1 and being obtained in positions substantially coinciding with electrical contacts 7 of the connectors 6. It may be noted, however, that in a position corresponding to each contact 7 not necessarily a window 11 is provided. In other words, following upon assembly of the device, the contact 7 of a connector 6 can be located in a position corresponding to a local portion of the insulating layer 9b, determined by the absence of a window 11; merely by way of example, one such local portion of the insulating layer 9b is designated by 11′ in
In a particularly advantageous embodiment of the invention the windows 11 are made with the same process used for obtaining the indication 4 on the layer of paint 9a deposited on the wall 3b so that, in one and the same processing step, and without any possibility of confusion, there will be made on the body 3 both the indication 4 and the corresponding succession of windows 11.
When the lower region of a side wall 3b is inserted in a corresponding connector 6, the contacts 7 set themselves up against the outer face of the wall itself, sliding thereon. In this way, the correspondence of a contact 7 with a window 11 opened on the conductive layer 10 or with a local portion 11′ of insulating layer 9b determines a binary succession, which enables the control system CS to which the device is connected to identify the identity of the indication element represented by the body 3 in a unique way. In the preferred embodiment, the contacts 7 are at least in part elastically deformable, in order to be coupled with the body 3, and in particular are configured in such a way that their active part 7′ is elastically pressed on the respective faces of the body 3, following upon coupling with the connectors 6; thanks to said characteristic, the electrical contact between the parts is improved, and the elastic reaction of the contacts 7 on the walls 3b ensures positioning of the body 3 without any vibrations.
In a preferred embodiment, the device 1 is provided with preferential or unique positioning means, for positioning the body 3 on the base 5, said means being arranged so as to prevent assembly of the body 3 on the base 5 with an orientation different from the design orientation. Said means can be obtained with any known modality; for said purpose, there may, for example, be provided one or more body references on the walls 3b and corresponding structures or seats on the base 5, or else pins may be provided on the lower face of the walls 3b and coinciding seats or passages on the base 5 (or vice versa): in this way, it is also possible to define in a unique and repeatable way one of the contacts 7 as reference contact, and likewise a corresponding window 11.
The methodologies for recognition of the succession of correspondences between the contacts 7 and the windows 11 or local portions 11′, performed by the control system CS, may be multiple. For example, by connecting a reference contact 7 to the positive pole of a voltage generator, via another contact 7 corresponding to a window 11 the control system CS can detect a passage of current from the aforesaid reference contact 7, through the conductive layer 10. In this way, the succession of the correspondences of the windows 11 and local portions 11′ with the contacts that are not reference contacts results in a succession of passage and non-passages of current, which can be interpreted substantially as digital signals in binary code. If we assume, by way of example, that for each face 3b of the body 3 two contacts 7 are present, of which a reference one, then the succession of readings of passage of current (correspondence between non-reference contact 7 and window 11) and of non-passage of current (contact 7 corresponding to a local portion 11′) there will be formed seven binary states (passage or non-passage), for a total of 27=128 possible different combinations. Once again purely by way of example and with reference to
In a preferred embodiment, irrespective of the reading method followed by the electronics CS for recognizing the succession of the correspondences between the contacts 7 and the windows 11 or local portions 11′, said method is set under way upon switching-on of the engine of the motor vehicle in order to identify a plurality of elements 3 belonging to the device 1, provided with corresponding indications 4, and all the information of identification and positioning is stored in memory means of the system CS. In another possible embodiment, and once again irrespective of the reading method, the information of identification and positioning of a plurality of elements 3 is stored in a durable way in memory means of the on-board electronics CS and is again stored (or modified in memory) only following upon an explicit command issued by the user, via a suitable input means (such as a key), particularly following upon change of the arrangement of the elements 3 on the dashboard that constitutes the user interface.
From what has been described previously, it may be understood how, in the user-interface device 1 according to the invention, the arrangement of the indication elements 3 can be configured according to the requirements, thanks to the presence of the identification means 9b, 10, 11, 11′ and of the detection means 6, 7, CS. For example, the device 1 can be equipped with different indication elements 3 according to the type of model of motor vehicle or to the corresponding on-board equipment (standard/optional). Likewise, the arrangement of the elements 3 that equip the device 1 can be varied subsequently, for example, according to the requirements or preferences of the final user, by simply repositioning the elements themselves within the openings provided in the device 1, at which, within the body 2, the corresponding connectors 6 are positioned. It emerges also clearly that, according to the invention, new indication elements 3 can be added to the ones originally provided on the device 1. With reference to the example of
The device 1 is preferably provided with means for securing in a removable way the elements 3 in the respective positions, it being possible also for said means to be obtained with any known modality. For example, with reference to
In a particularly advantageous embodiment of the invention, which may form the subject of an independent patent protection, associated to one or more reference elements 3 is a back-lighting system.
For said purpose, the body 3 is hollow and is made of a transparent plastic material, such as, for example, polymethyl methacrylate or polycarbonate, and associated to the base 5 are light-generating means. In the example illustrated, said means comprise two distinct light sources 12a and 12b, supplied via electrically conductive paths 13, connected to an electrical-supply source (not represented). The sources 12a, 12b are preferably semiconductor sources, such as LED sources adapted to be mounted with surface-mount technology (SMT), or else chipLED sources, adapted to be mounted with chip-on-board (COB) technology.
In the example, positioned on the vertical of the sources 12a, 12b is an optical module 14, having a body made of transparent material, such as, for example, polymethyl methacrylate or polycarbonate. The module 14 is configured for collecting the light emitted by the light-generating means 12a, 12b and create at output a cone of rays of pre-set semidivergence α and a uniform lighting profile, of pre-set shape and dimensions, in a plane designated by 15 in
Once again with reference to the particularly advantageous embodiment illustrated, the module 14 has a main optical axis, designated by 16 in
the rays emitted by the source are refracted by the lens and deflected in such a way that the direction of the rays leaving the lens itself coincides with the direction that the rays would have had in the case where they had been emitted by a virtual source, set at a distance “S1” from said lens and on the same side (with respect to said lens) of the real source of the rays. The angular semidivergence α of the cone of rays leaving said lens is such that
where Φ/2 is the half-diameter of the aforesaid lens.
Hence, it follows that, given a lens of diameter Φ and focal length f, in paraxial approximation the distance S0 of the light source from said lens determines the semidivergence α of the beam of rays leaving said lens. In the case of the advantageous embodiment described, the semidivergence α of the beam of rays emitted by the light-generating means 12a, 12b and leaving the second surface 14b of the optical module 14 may be, to a first approximation, evaluated in a similar way.
In a preferred embodiment each of the two surfaces 14a, 14b is obtained by rotation about the optical axis 16 of a portion of conical curve (for example, the arc of a circumference, the arc of a parabola, of the arc of a hyperbole) and the uniformity of lighting on the plane 15 is achieved in an approximate way. In another preferred embodiment, at least one of the two surfaces 14a, 14b is obtained by rotation of a portion of aspherical curve, described for example by the following formula:
(where “c” is the curvature of the surface, “k” is the conicity factor and “αi” are the asphericity factors) and optimized, following one of the known approaches, so that the lighting profile generated by the optical module 14 on the plane 15 set at a distance d0 will be uniform.
In general terms, given the small size of the indications 4 with respect to their distance d0 from the base 5 on which the light-generating means 12a, 12b are set, the surfaces 14a, 14b of the module 14 can be simple portions of spherical caps, without the lack of uniformity introduced on the lighting profile being perceived as troublesome by the user. However, in the case where the extension of the indications 4 is approximately comparable to or greater than the distance d0, then it is preferable for at least one of the surfaces 14a, 14b to present an aspherical profile, in order to minimize any lack of uniformity of the lighting profile in the plane 15 and, consequently, any lack of uniformity of luminance of the indications 4 perceived by the user.
In a further embodiment, the upper wall 3a of the hollow body 3 has at least one of its two faces (the outer face and/or the inner face) that is not smooth, or distinguished by a certain degree of surface roughness, in such a way that a beam of collimated light impinging upon it from a direction normal to the face itself will not traverse the wall 3a unperturbed, but rather will be diffused, i.e., its angular divergence will be increased, with a characteristic angle of diffusion δ. It is known that, when a light beam of divergence α traverses a wall of which at least one of the two faces is a diffusing surface and is characterized by an angle of diffusion δ, then the final divergence αf of said light beam leaving said wall can be, to a first approximation, determined as the quadratic sum of said initial divergence α and of said angle of diffusion δ, namely:
αf2=α2+δ2
The presence of at least one face that diffuses with an angle of diffusion δ enables the user to perceive the uniformity of lighting of the indication 4 as uniformity of luminance. By appropriately combining the divergence α introduced by the optical module 14 with the characteristic angle of diffusion δ introduced by the surface roughness of at least one of the two faces of the top wall 3a it is possible to obtain, at output from the reference 4, a light beam of desired divergence αf and, consequently, obtain a reference that is uniformly illuminated with an angle of visibility αf.
In one embodiment, in the case where the light-generating means comprises at least two sources, as in the case exemplified in the figures, the latter can have a different colour or spectral peak of emission, in such a way that the indication 4 will be perceived by the user with a different colouring according to whether just one source 12a, 12b is lit up, or else a combination of said sources with the same or different intensity.
In on embodiment, one of the two sources 12a, 12b lights up in order to back-light the indication 4 and signal the position thereof, whilst the other of said sources 12a, 12b lights up to signal activation of the command, or occurrence of the event corresponding to the indication 4.
In a possible embodiment of the invention, different from the one exemplified in the figures, the indication 4 is on an input or command element, such as a key that can be operated by the user, the body of which substantially corresponds with the body 3, and operation of which is obtained according to known techniques, for example, with a mono-stable or bi-stable push-button system carried by the base 5: in this case, the identification of the indication 4 coincides with the identification of the command associated to the key and is carried out upon starting of the motor vehicle. In another embodiment, the identification of the key is performed whenever the key is depressed, in such a way that the on-board electronics CS will simultaneously record that pressure has been applied and identification of the command associated to the pressure applied.
Of course, without prejudice to the principle of the invention, the details of construction and the embodiments may vary widely with respect to what is described and illustrated herein purely by way of example, without thereby departing from the scope of the present invention.
In the case of a user-interface device without back-lighting system, the body 3 may also be a non-hollow body, it being sufficient for the conductive layer 10 and the insulating layer 9b having the windows 11 and/or local portions 11′ to be provided on its outer walls, according to what has been described previously.
It is then evident that, if need be, the connectors 6 can be configured in such a way that the contacts 7 will co-operate with the internal face of the walls 3b, in which case it will be said internal face that is provided with the conductive layer 10 and insulating layer 9b, as well as windows 11 and local portions 11′ of the insulating layer. In order to increase the encoding possibilities, moreover, first and second contacts can be provided for being set up against, respectively, the outer face and the inner face of one or more walls 3b, said faces being both provided with the conductive layer 10 and insulating layer 9b, as well as with windows 11 and/or local portions 11′.
The contacts 7 could also be associated directly to the substrate 5, i.e., without the corresponding body connector 6, and come up from said substrate in a vertical direction.
Finally, it emerges clearly that the general shape of the body of the indication elements 3, whether these are command keys or else just elements for signalling information, may be different from the one exemplified, even with a number of side walls different from the one exemplified, to which there may correspond respective connectors. It is likewise clear that the encoding means 9b, 10, 11, 11′ described could possibly be present also on a single side wall of the body 3, providing a corresponding connector 6 with an adequate number of contacts 7.
Number | Date | Country | Kind |
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09425049.5 | Feb 2009 | EP | regional |
This application is a continuation of U.S. patent application Ser. No. 12/934,901, filed 27 Sep. 2010, which is the U.S. national phase of International Application No. PCT/IB2010/050321 filed 25 Jan. 2010, which designated the U.S. and claims priority to EP Application No. 09425049.5 filed 11 Feb. 2009, the entire contents of each of which are hereby incorporated by reference.
Number | Date | Country | |
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Parent | 12934901 | Sep 2010 | US |
Child | 13693027 | US |