EP4315086A1 - Method for adapting a peripheral to any type of operating system - Google Patents

Abstract

The invention relates to a method for automatically adapting a first digital peripheral (2) comprising a set of interaction means (4) capable of emitting a first set (S1) of digital signals that are compatible with an operating system of a first information processing machine (3), the adaptation method comprising: - a step (P11) of identifying an operating system of a second information processing machine (3') to which the first device (2) is connected, then - a step (P12) of associating a second set (S2) of digital signals that are compatible with the operating system of the second information processing machine (3') with interaction means (4) and/or with combinations of interaction means (4) of the first peripheral (2), the steps (P11, P12, P13) of identification, association and transmission being implemented by means of a microprocessor (5) integrated in the first peripheral (2).

Description

DESCRIPTION

TITLE: Process for adapting a peripheral to any type of operating system

Technical field of the invention

The invention relates to a method for automatically adapting a digital peripheral such as a computer mouse, a keyboard or a joystick. The invention also relates to a digital peripheral configured to implement such an adaptation method. The invention also relates to a computer system comprising such a digital peripheral.

PRIOR ART Digital peripherals, sometimes also referred to as "controllers", are interfaces allowing a user to send digital signals to an information processing machine. The most commonly used peripherals are, for example, a keyboard, a mouse or a joystick. Information processing machines are, for example, computers or game consoles. Digital peripherals are therefore equipment used daily to transmit commands to information processing machines. There is a need to increase the diversity of the commands transmitted by the digital peripherals, that is to say the bit rate of information that a user can transmit to an information processing machine. To this end, manufacturers offer peripherals equipped with a greater number of means of interaction: keyboards always include more keys, mice include more buttons and/or additional means of interaction such as for example wheels or joysticks that can be activated with the thumb. Gamepads also increasingly include more buttons and/or various means of interaction involving all the fingers or almost all the fingers of both hands.

Devices are therefore increasingly complex. They are more expensive to manufacture and require more learning time to handle them effectively. On the other hand, once this learning has taken place, a user can become much more efficient in controlling information processing machines.

There is also a wide variety of information processing machine. Each of these machines is equipped with its own operating system and is only compatible with certain peripherals. It is sometimes possible to install computer drivers to make a given peripheral compatible with an information processing machine. However, computer drivers are not always available and their installation can be complex. Thus, a user must familiarize himself with an ever-increasing number of devices. He must constantly reaccustom himself to the gestures specific to the manipulation of these peripherals. This diversity prevents him from perfecting the use of the same and unique peripheral and encourages him to equip himself with peripherals that are relatively simple to use.

Adapters are known, in the form of a USB key, intended to be connected to a personal computer. These adapters are configured to make possible the use of a controller initially intended to operate with an Xbox® game console, with a personal computer equipped with a Windows10® operating system. These adapters are cumbersome to use as it requires specific equipment that needs to be plugged in. In addition, they do not allow the said controller to be used with machines other than a personal computer equipped with the Windowsl O® operating system.

Presentation of the invention

The object of the invention is to provide a method for adapting a digital peripheral remedying the above drawbacks and improving the peripherals known from the prior art.

More precisely, a first object of the invention is a method for adapting a peripheral making it possible to make the peripheral compatible with any operating system of any information processing machine, without having to installing software on said information processing machine.

Summary of the invention

The invention relates to a method for automatically adapting a first digital peripheral comprising a set of interaction means capable of being actuated by a user, the first peripheral being capable of transmitting a first set of digital signals compatible with a operating system of a first information processing machine following actuation of the interaction means, the adaptation method comprising:

- a step of identifying an operating system of a second information processing machine to which the first peripheral is connected, then

- a step of associating a second set of digital signals compatible with the operating system of the second information processing machine with means of interaction and/or with combinations of means of interaction of the first peripheral , then

- a step of transmission, by the first peripheral, of a digital signal of the second set when the means of interaction or the combination interaction means previously associated with this digital signal is actuated, the steps of identification, association and transmission being implemented by means of a microprocessor integrated in the first peripheral.

The step of identifying an operating system of the second information processing machine may comprise the identification of a digital signal transmission protocol compatible with the operating system of the second information processing machine information.

Said digital signal transmission protocol can be defined by a type of data expected by the operating system of the second information processing machine, the type of data being chosen from among at least one type of data relating to events of the first peripheral, and/or a type of data relating to the state of the first peripheral.

Said digital signal transmission protocol can be defined by a condition for sending a digital signal, the condition being chosen from at least one condition according to which the first peripheral transmits data spontaneously according to a recurrence rule, and/or a condition according to which the first peripheral sends data following a request from the operating system.

A function of at least one first interaction means of the first peripheral can be to modify the digital signal associated with at least one second interaction means of the first peripheral when said at least one first interaction means is actuated. The first peripheral may be a manual control peripheral of an information processing machine.

The first device can be a computer mouse or a gamepad.

The first peripheral may be a computer mouse, and the computer mouse may include at least one button, the transmitting step comprising transmitting a first digital signal of the second set when the at least one button is pressed in combination with a translational movement of the mouse on a support in one direction, the emission step comprising the emission of a second digital signal of the second set when the at least one button is not actuated in combination with a translational movement of the mouse on a support in said direction.

The adaptation process may include:

- a step of identifying a second digital peripheral capable of transmitting the second set of digital signals,

- a step of identifying at least one means of interaction of the second peripheral, the second peripheral being capable of transmitting at least one digital signal of said second set following actuation of the at least one means of interaction of the second device,

- a step of identifying at least one manual gesture allowing a user to actuate said at least one interaction means of the second peripheral,

- a step of associating at least one digital signal of said second subset with at least one means of interaction of the first peripheral, the at least one means of interaction of the first peripheral being intended to be actuated by said at least one manual gesture allowing a user to actuate said at least one interaction means of the second peripheral or by a similar gesture.

The adaptation method may comprise a step of calculating a number of first interaction means of the first peripheral whose function is to modify the digital signal associated with at least one second interaction means of the first peripheral when said first means of interaction are actuated.

The adaptation method may comprise a step of calculating a number of digital signals compatible with the operating system of the second information processing machine for which no interaction means and/or combination of interaction means of the first device is associated.

The invention also relates to a digital peripheral comprising a set of interaction means, a microprocessor and a memory, the peripheral being configured to implement the adaptation method as defined above.

The invention also relates to a computer system comprising an information processing machine and a peripheral as defined above.

The invention also relates to a computer program product comprising program code instructions recorded on a computer-readable medium to implement the steps of the adaptation method as defined above when said program runs on a computer. The invention also relates to a data recording medium, readable by a computer, on which is recorded a computer program comprising program code instructions for implementing the adaptation method as defined above.

Presentation of figures

These objects, characteristics and advantages of the present invention will be explained in detail in the following description of a particular embodiment given on a non-limiting basis in relation to the attached figures, among which:

FIG. 1 a schematic view of a computer system comprising an information processing machine and a peripheral according to one embodiment of the invention.

Figure 2 is a schematic view of a computer mouse.

Figure 3 is a schematic view of a gamepad.

detailed description

FIG. 1 illustrates a computer system 1 comprising a digital peripheral 2 and an information processing machine 3 according to one embodiment of the invention. Peripheral 2 is an item of equipment, or interface, allowing a user to send digital signals to the information processing machine. The peripheral comprises a set of interaction means 4. Four interaction means are represented in FIG. 1, however this number can be arbitrary. The means of interaction can be, for example, buttons, keys, sliders or potentiometers, wheels, position sensors, displacement sensors, accelerometers, optical sensors, or even audio sensors, or any combination death different ways. The peripheral 2 is preferably a portable peripheral, intended to control the information processing machine 3 such as a personal computer and/or a game console. In particular, the peripheral can be intended to be controlled manually. It may for example be a peripheral intended for leisure and/or entertainment. The peripheral 2 can for example be a keyboard, a computer mouse or even a joystick, or even any other form of peripheral with any number of interaction means and any arrangement of these means. The peripheral is said to be “digital” because it is able to emit digital signals when the means of interaction 4 are actuated by a user.

The peripheral 2 also comprises a microprocessor 5, a memory 6 and means 7 for transmitting and receiving digital signals. The microprocessor 5 is connected to the means of interaction 4, to the memory 6 and to the means of transmission and reception 7.

Peripheral 2 is connected to information processing machine 3 via its transmission and reception means 7. The connection between the peripheral and the information processing machine can either be a wired connection or a wireless connection, for example according to the Bluetooth standard, Wifi or any other equivalent standard.

The information processing machine 3 is able to receive the digital signals from the peripheral 2 and to interpret them. Advantageously, the information processing machine 3 can be connected to a screen 8, or monitor, allowing a user to view information. The information processing machine 3 can for example be a desktop computer, a laptop computer, a game console, a television, a tablet and more generally any computer equipment with which a user is likely to interact. The machine of information processing 3 comprises means for transmitting and receiving digital signals 9, a microprocessor 10 and a memory 11 in which an operating system is loaded. The operating system is a software allowing in particular to interpret the digital signals of the peripheral in control commands. The operating system may be, by way of non-exhaustive example, an operating system for a computer such as Microsoft Windows ®, an operating system for an Apple ® computer, for a game console such as the game consoles of brand Sony Playstation ®, Nintendo Switch ® or Microsoft Xbox ®.

FIG. 2 illustrates an embodiment of the peripheral 2. In this case the peripheral 2 is a computer mouse, more simply called “mouse” hereafter. The mouse is a device intended to be moved on a support by a single hand of a user. The mouse includes a sensor to measure its movement on the support on which it rests. By way of example, the mouse shown is a right-handed mouse. It comprises a first so-called "left click" button 21, intended to be clicked with the index finger of the right hand. It also includes a second so-called "right-click" button 22 intended to be clicked with the middle finger of the right hand. Between the first button and the second button, the mouse comprises a wheel 23 which can rotate around a transverse axis. This wheel can be turned forwards or backwards, for example with the index finger of the right hand. This wheel can also be clicked down like a button. The mouse further comprises a third button 24 positioned at the rear of the wheel 23. The mouse further comprises a fourth button 25 and a fifth button 26 arranged on a left side of the mouse. These two buttons 25, 26 can be activated with the thumb of the right hand. Finally, the mouse also comprises a joystick 27 which can be activated with the thumb. This joystick 27 can be oriented in four directions: forwards, backwards, upwards, or downwards. down. It can also be oriented in any intermediate direction defined between these four directions. The inclination amplitude of the joystick 27 inch can be variable. The mouse is therefore capable of emitting a set of digital signals corresponding to its various means of interaction. Depending on the nature of the interaction means, the corresponding digital signal can convey different data, in particular a greater or lesser amount of information. For example, the digital signal associated with the use of a button can only convey binary data corresponding to pressing or not pressing the button. The digital signal associated with the joystick 27 can convey data whose value depends on the amplitude of inclination of the joystick in a given direction. Of course, the mouse also comprises a sensor (not shown) making it possible to detect a displacement in translation of the mouse on a support.

In the table presented below, the mouse can emit a set S1 of sixteen digital signals S1-1 to S1-16.

[Table 1]

As a side note, in this document front, back, left, right, bottom and top are defined from a device user's point of view. Top and bottom are defined with reference to a vertical or substantially vertical axis. The back is the side of a device substantially towards the user's body while the front is the side of the device opposite the back.

The memory 6 of the peripheral 2 comprises at least three sets of data, that is to say three sets of information which can for example be in the form of lines of code, lists, correspondence tables, or even in any other form capable of being used by the microprocessor 5.

A first set of data includes a list of operating systems and a numerical identifier associated with that operating system. Advantageously, when a peripheral 2 is connected to an information processing machine, an initialization protocol is automatically executed: the information processing machine automatically transmits a digital signal containing a digital identifier. The reception of this numerical identifier by the peripheral 2 makes it possible, thanks to the first set of data, to identify the operating system of the information processing machine 3 to which the peripheral is connected.

A second set of data comprises data defining a protocol for transmitting digital signals according to each operating system identifiable via the first set of data. Each operating system has its own protocol governing the transmission of digital signals by the devices connected to it. A transmission protocol is a set of rules that a given device must follow so that the digital signals it transmits can be correctly interpreted by the operating system. In particular, the transmission protocols mentioned relate to high-level protocols, or in other words application protocols. They concern the logical structure of digital signals, that is to say the way in which the information they convey is coded within these digital signals, and not their physical structure. The protocol for sending digital signals notably governs the type of data expected by the operating system and the conditions for sending these digital signals. In other words, the second set of data comprises digital signal configuration data compatible with each of the operating systems identifiable via the first set of data.

The peripheral 2 is thus capable of transmitting digital signals according to different types of transmission protocols, that is to say according to different types of information coding. As regards the type of data expected by the operating system, that is to say the nature of the data expected by the operating system, according to a first option, the data expected by the operating system can relate to events that have occurred on the various means of interaction 4. The data transmitted then contain the last physical events that have occurred on the peripheral since the last transmission of data. Data of this type is event-based. They are also designated by the anglicism "Event Based Data". According to a second option, the data expected by the operating system can relate to the states of the various means of interaction 4. The data then indicate the current state of one or more means of interaction, independently of the events which led there. Data of this type is state-based. They are also designated by the anglicism "State Based Data".

According to a third option, the data expected by the operating system can relate both to events occurring on the various means of interaction and both to the states of the various means of interaction. Data of this type is also referred to as "Hybrid Data".

With regard to the conditions of transmission of these digital signals, according to a first option, the peripheral 2 is an active peripheral, that is to say that it transmits a digital signal spontaneously according to a rule of recurrence. For example, the recurrence rule can define that the signal is transmitted each time the state of an interaction means is modified and/or each time a time countdown reaches zero.

According to a second option, the peripheral is passive, ie it emits a digital signal following a request from the operating system of the information processing machine 3 to which it is connected.

Finally, according to a third option, the peripheral is hybrid and behaves like an active and passive peripheral. The device proactively sends data according to a recurrence rule like an active device, and also responds to operating system requests like a passive device. Finally, by combining the three different types of data sent by the peripheral and the three different conditions for sending digital signals, it is possible to define nine protocols for sending digital signals. The table below summarizes embodiments of these nine transmission protocols.

[Table 2

Finally, a third set of data in the memory 6 of the peripheral 2 comprises, for each operating system identifiable via the first set of data, the association of an interaction means 4 and/or of a combination of means interaction 4 with a digital signal compatible with said operating system.

The elaboration of these three sets of data can be carried out during the design phase of the peripheral 2. Then, the sets of data can be loaded into the memory 6 during a process of manufacture of the peripheral 2. Advantageously, the peripheral can comprise updating means for completing and/or correcting the sets of data loaded into the memory 6. For example, these updating means can make it possible to update the identifiers existing operating systems, and/or signal transmission protocols, and/or associations of interaction means 4 and/or combinations of interaction means 4 with digital signals. Configuration software can also be provided to modify the different sets of data and thus personalize the operation of the peripheral 2.

The invention also relates to a method making it possible to efficiently produce such data sets, and in particular the third data set mentioned above. The process which will be described makes it possible to create an association between, on the one hand, interaction means 4 of peripheral 2 and/or a combination of interaction means 4 of peripheral 2 and, on the other hand, a set of digital signals compatible with a given operating system. The development process makes it possible to obtain an association that is as ergonomic and intuitive as possible. This generation method is a generic method that can be implemented for each operating system with which the peripheral is likely to cooperate. When a new operating system appears on the market, it is easy to update the sets of data governing the operation of the peripheral 2 so that it becomes compatible with this new operating system.

An embodiment of the production method can be broken down into four steps P1 to P4. This method aims to make the peripheral 2 compatible with a second information processing machine 3′, distinct from the information processing machine 3 previously described (known as the first information processing machine). As a side note, the terms "first" and "second" are only intended to distinguish two distinct objects. These terms should not be interpreted as conferring any particular hierarchy on these objects.

In a first step P1, a peripheral 2′ specifically designed to operate with an operating system of the information processing machine 3′ is identified. Subsequently, the peripheral 2' will also be designated by the term “second peripheral” or “target peripheral” to distinguish it from the peripheral 2, called “first peripheral” or “source peripheral”. For example, the peripheral 2' can be a peripheral specifically designed to work with the operating system of the information processing machine 3'. For example, if the operating system in question is the operating system of a Microsoft Xbox® console, the 2' device may be a Microsoft Xbox® controller, sold with this console. FIG. 3 illustrates, by way of example, the second peripheral 2', which in this case is a joystick, and is compatible with the operating system of the information processing machine 3'.

In a second step P2, the various interaction means 4' of the second peripheral 2' are identified. The second peripheral 2' comprises two handles 21' and an upper face provided with eight buttons 221', 222', 223', 224', 225', 226', 227', 228', a directional pad 23' operable with the thumb of the left hand, a first joystick 24' and a second joystick 25' respectively adjustable with the thumb of the left hand and the thumb of the right hand to the right, to the left, forwards or backwards or again towards any intermediate orientation between these four orientations. The peripheral 2' is therefore capable of transmitting a set of digital signals corresponding to its various means of interaction 4'. In the present case, the peripheral 2' can emitting a set S2 of digital signals S2-1 to S2-20. The means of interaction 4' associated with each of these digital signals are presented in the table below.

[Table 3]

The digital signals S2-1 to S2-20 form a second set S2 of twenty digital signals compatible with the operating system 3'. In a third step P3, manual gestures are identified allowing a user to actuate the various means of interaction 4′ of the peripheral 2′. Indeed, each device is designed to be used with a particular grip. During this step, this grip and the gesture necessary to actuate each means of interaction 4′ are therefore identified, in particular the finger(s) of the hand which are solicited. In this case, given the ergonomics of the peripheral 2', it is designed to be held with both hands with the two handles 21' in the palm of each hand. The various interaction means 4' are intended to be actuated with the thumbs of the right hand and of the left hand. As a variant, the peripheral 2′ could of course have any shape and/or be intended to be manipulated with one hand, or with any other gesture. For example, the peripheral 2' could also comprise additional buttons arranged on a lower face and/or on a rear face comprising buttons or triggers operable with the index, middle, ring or little finger of each hand. During this third step P3, it is possible to determine for each means of interaction 4′, the finger and/or the manual gesture necessary for its actuation.

In a fourth step P4, each of the digital signals that the terminal 2' can emit is associated with an interaction means and/or a combination of interaction means of the first peripheral 2. Preferably, for each digital signal of the peripheral 2' or at least for most of them, the digital signal is associated with a means of interaction of the peripheral 2 which is operable by the same gesture or a similar gesture (for example with the same finger of the main) on device 2'. By proceeding in this way, the peripheral 2, although not designed specifically to deliver the second set S2 of digital signals, can be manipulated as close as possible to the peripheral 2'. Handling the device 2 connected to the information processing machine 3' will therefore be particularly intuitive.

For example, the second joystick 25' of the peripheral 2' can be operated with the thumb of the right hand. This 25' joystick allows digital signals S2-17, S2-18, S2-19 and S2-20 to be transmitted depending on the direction in which it is oriented. On peripheral 2, joystick 27 can also be operated with the thumb of the right hand. Thus, during the fourth step P4, the signals S2-13, S2-14, S2-15 and S2-16 will preferably be associated with the different possible orientations of the joystick 27 on the peripheral 2.

The peripheral 2' may optionally comprise a greater number of interaction means than the peripheral 2. For example, the first peripheral 2 of FIG. 2 comprises sixteen interaction means while the second peripheral 2' comprises twenty means of interactions. In this case, it is advantageously possible to use a combination of interaction means 4 of the second peripheral 2 to transmit with the peripheral 2 a number of digital signals greater than the number of interaction means available. The number C of possible combinations for a peripheral comprising a number N of independently operable interaction means is given by the following formula:

[Math 1]

C = 2 ^N - 1

In the event that the peripheral 2 comprises means of interaction which cannot be actuated independently, the number of C possible combinations could be obtained by a different formula (for example, the joystick 27 cannot be actuated simultaneously towards the forwards and backwards; the mouse cannot be moved simultaneously in translation to the right and to the left). However, we understand that it is possible to produce a very large number of different digital signals by combining the interaction means of a peripheral such as the mouse of FIG. 2. Advantageously, when the first peripheral 2 comprises a number of interaction means lower than the second peripheral 2', one or more first means of interaction of the first peripheral 2 are defined, the function of which is to modify the digital signal associated with at least one second means of interaction of the first peripheral 2 when it is actuated. Such a first interaction means can also be called “modifying interaction means”. It can be compared to the "Alt" or "Ctrl" key on a keyboard which, when pressed, modifies the digital signals emitted by the keyboard when any other key is pressed.

For example, with the peripheral 2 of FIG. 2, it is possible to define that the button 22, called the right-click button, is a modifying means of interaction. When the button 22 is pressed, the simultaneous actuation of any other means of interaction 21, 23, 24, 25, 26, 27 or the simultaneous movement of the mouse on its support generates the emission of a digital signal different from the one that would be sent if button 22 was not pressed.

The invention thus proposes to reproduce, with the mouse of FIG. 2, the digital signals associated with the manipulation of the directional pad 23' and with the manipulation of the first joystick 24' of the peripheral 2'. The digital signals associated with the manipulation of the directional pad 23' can be emitted by the peripheral 2 by moving it by translation on a support: a displacement of the peripheral 2 to the right can thus generate the same digital signal that would generate pressing on the part right of the 23' directional pad of the 2' peripheral. The same goes for a displacement of the peripheral 2 by translation upwards, downwards left or down, or any other intermediate direction between these four main directions. The digital signals associated with the manipulation of the first joystick 24' can be transmitted by the peripheral 2 by moving it by translation on a support while keeping the button 22 pressed. Thus, the peripheral 2 is able to emit different digital signals depending on whether the button 22 is pressed or not. It is thus possible, thanks to the combination of a movement in translation of the peripheral 2 and the selective depression of a button, to reproduce the eight digital signals S2-9 to S2-16. As a side note, the use of such a modifying interaction means prevents the simultaneous transmission of one of the signals S2-9 to S2-12 with one of the signals S2-13 to S2-16. This slight inconvenience can easily be admitted because the directional pad 23' and the first joystick 24' are both designed to be operated with the thumb of the left hand. The operating system of the second information processing machine 3' therefore normally assigns no function to the simultaneous actuation of the interaction means 23' and 24'.

The following table shows, by way of example, an association between the means of interaction 4 of the first peripheral 2 and combinations of these means of interaction with the signals S2-1 to S2-20.

[Table 4]

According to the above example, it is therefore possible to reproduce the twenty signals S2-1 to S2-20 by using only thirteen means of interaction (the wheel 23 not being used). In the event that it is desired to produce a greater number of different digital signals, it is possible to use two or even more modifier interaction means.

Advantageously, the generation method includes a step P5 of calculating a number of modifier interaction means necessary to produce a given number of digital signals. In some more extreme cases, it is possible that the number of interaction means 4 of the peripheral 2 is insufficient to reproduce all the digital signals that another peripheral 2' can emit, even using a large number of modifying interaction means. . Such a situation can for example occur if the first peripheral 2 comprises a restricted number of means of interaction (for example a mouse comprising only two buttons) and that one seeks to reproduce all the digital signals produced by a second peripheral 2' comprising a large number of interaction means (for example a computer keyboard comprising 100 keys or more). In this case, it can be decided that certain digital signals of the second peripheral 2′ will not be associated with an interaction means or with a combination of interaction means of the first peripheral. Preferably, the digital signals from the second peripheral 2' deemed the least useful will thus be discarded, that is to say they will not be associated with any means of interaction or combination of means of interaction of the first peripheral 2 Advantageously, the generation method comprises a step P6 of calculating the number of digital signals of the second set of digital signals which cannot be associated with an interaction means or with a combination of interaction means of the first peripheral.

Steps P5 and P6 can be implemented by the same algorithm, an example of which is given below. In this algorithm, the following nomenclature is used:

- n_s designates the number of means of interaction of the first peripheral,

- n_t designates the number of means of interaction of the second peripheral,

- t_supp designates the number of digital signals of the second set of digital signals which must be discarded,

- x denotes the number of means of modifier interaction required, - "find" is a boolean useful only for the purposes of the algorithm,

- the sign "!" is used to designate the inverse sign of a given boolean,

- "ceil" designates the "rounded up" function. If n_s <2 V(n_t ) - 1 then Int t_supp = 0

Int x = Max(0;ceil(1/2 (n_s + V((n_s + 1) ^L 2 - 4n_t ) -1)))

Otherwise

Int t_supp = 0 Bool found = FALSE

While !finds do Int x = 0

If n_s > n_t - t_supp then find = TRUE Break;

Otherwise

X = 1

While n_s-x > 0 and (n_s - x)(x! + 1 ) < n_t do x++ End while

If n_s-x > 0 and (n_s - x)(x! + 1 ) ³ n_t then find = TRUE Break

End If End If t_supp++

End While

End If An interaction means 4' of the second peripheral 2' is preferably substituted by an interaction means 4 of the same nature of the peripheral 2. However, when the first peripheral 2 is not equipped with an interaction means of the same nature as an interaction means of the second peripheral 2′, it is still possible to reproduce the digital signals associated with the interaction means. of the second peripheral 2' with a substitution interaction means of the first peripheral 2. The invention thus proposes a preference table identifying for each type of interaction means 4', an interaction means 4 to be chosen in order of preference. An example of such a preference table, or preference matrix, is shown below. In this table the following abbreviations are used: "B" means "button", "CBL" means "combination of buttons", "CD" means "displacement sensor", "S" means "potentiometer", CS means "combination of potentiometer", "CP" means "position sensor", "CO" means "optical sensor", and "CA" means "audio sensor". [Table 5]

If choice 1 is not possible, the interaction means 4' is replaced by an interaction means 4 according to choice 2, and so on up to choice 8 which is the least preferred choice. For example, the digital signals S2-13 to S2-16 are associated with inclinations of the first joystick 24' forward, backward, left and right respectively. The joystick can take a multitude of inclinations between its rest position and its stop position. Thus the joystick 24' is likened to a combination of potentiometers. To generate the digital signals S2-13 to S2-16 with the peripheral 2, an interaction means is preferably used which is also a combination of potentiometers. If peripheral 2 does not include any combination of potentiometers or if these are already associated with the emission of other digital signals, one seeks to apply choice number 2, i.e. to generate the digital signals S2- 13 to S2-16 with a single potentiometer (for example wheel 23 can be seen as a potentiometer). If peripheral 2 does not include any potentiometer or if these are already associated with remission of other digital signals, we seek to generate digital signals S2-13 to S2-16 with choice 3, i.e. button combinations, and so on.

In the event that an interaction means is substituted by an interaction means of a different nature, it is possible advantageously to use a transfer function to convert the digital signal associated with a given interaction means into a digital signal of a different form. .

At the end of the elaboration process which has just been described, a peripheral device 2 configured to implement an automatic adaptation process according to one embodiment of the invention is available. We now describe this adaptation method, which corresponds to a method of using the peripheral 2.

Initially, it is considered that the peripheral 2 is connected to the information processing machine 3 and that it is configured to emit the digital signals S1-1 to S1-16 compatible with the operating system of the processing machine. information 3. The process aims to make the device compatible with any type of operating system. In particular, we now explain the steps making it possible to make the peripheral 2 compatible with the operating system of the second information processing machine 3′.

In a first step P11, the peripheral 2 is connected to the information processing machine 3′, for example by a connection. When the peripheral 2 is connected to a data processing machine, an identifier of the operating system is automatically transmitted. This identifier is then used as input to the first set of data to identify the operating system. It is thus possible to identify the operating system of the information processing machine 3′ to which the peripheral 2 is connected. It is then possible to deduce therefrom the set S2 of digital signals compatible with the information processing machine 3'.

Following the identification of the operating system, the protocol for transmitting the digital signals from the peripheral 2 is adapted so that they are compatible with the operating system of the information processing machine 3'. This adaptation is based on the second set of information. In particular, the digital signal transmission protocol is defined by the type of data expected by the operating system and the type of condition for transmitting a digital signal.

In a second step P12, the second set of digital signals S2-1 to S2-20 compatible with said operating system 3' is associated with the interaction means 4 and/or combinations of interaction means 4 of the first peripheral. This association step is based on the third set of data. Then, in a third step P13, the first peripheral 2 transmits a digital signal from among the signals S2-1 to S2-20 following actuation by a user of the interaction means or of the combination of interaction means associated with this digital signal. For example, following the association proposed in table 4, a movement in translation to the right of the mouse 2 leads to the emission of the digital signal S2-12, this signal being normally associated with a press on the right of the directional pad 23 ' of controller 2'.

The user can therefore use the peripheral 2 to transmit digital signals compatible with the operating system of the second information processing machine 3'. The user can therefore use the same peripheral 2 more often and become familiar with the grip which is specific to him. It does not have to equip itself with new peripherals to communicate with new operating systems.

Steps P11, P12 and P13 are implemented by means of a microprocessor integrated in the first peripheral. Thus, the adaptation method is completely independent of the information processing machine to which the peripheral is connected. The adaptation of peripheral 2 does not require the calculation resources of the information processing machine. The use of the peripheral 2 according to the invention does not require any installation of a computer driver on the information processing machine. In other words, the use of the peripheral 2 instead of the peripheral 2' is completely transparent for the second information processing machine 3'.

Thanks to the invention, it is therefore possible to automatically transform the peripheral 2 to make it compatible with a second information processing machine 3′, different from the processing machine information 3. This transformation is virtual: it does not induce any physical modification of the peripheral 2. The user can therefore use the same peripheral 2 as soon as the latter is connected to an information processing machine whose system exploitation is recognized. Of course, the peripheral 2 is not intended to communicate simultaneously with the two information processing machines 3 and 3'. The method of adapting the peripheral 2 can be seen as a method of imitating a peripheral 2′ compatible with a given operating system. The example which has been given makes it possible to virtually transform a computer mouse into a joystick. However, the invention is not limited to this example. The invention can also be applied, for example, to virtually transform a mouse into a keyboard for a computer or into a remote control for a television. Inverse transformations are also possible: for example, a joystick can be virtually transformed into a computer mouse, a keyboard or a remote control.

Claims

1. Method for automatic adaptation of a first digital peripheral (2) comprising a set of interaction means (4) capable of being actuated by a user, the first peripheral being capable of transmitting a first set (S1) of signals compatible with an operating system of a first information processing machine (3) following actuation of the interaction means, the adaptation method comprising: - a step (P11) of identifying an operating system of a second information processing machine (3') to which the first peripheral (2) is connected, then

- a step (P12) of associating a second set (S2) of digital signals compatible with the operating system of the second information processing machine (3') with interaction means (4) and /or with combinations of means of interaction (4) of the first peripheral (2), then

- a step (P13) of transmission, by the first peripheral (2), of a digital signal from the second set (S2) when the means of interaction or the combination of means of interaction previously associated with this digital signal is actuated, the steps (P11, P12, P13) of identification, association and transmission being implemented by means of a microprocessor (5) integrated in the first peripheral (2).

2. Adaptation method according to the preceding claim, characterized in that the step (P11) of identifying an operating system of the second information processing machine comprises the identification of a protocol of transmission of digital signals compatible with the operating system of the second machine information processing.

3. Adaptation method according to the preceding claim, characterized in that said digital signal transmission protocol is defined by a type of data expected by the operating system of the second information processing machine (3 ') , the type of data being chosen from among at least one type of data relating to events of the first peripheral, and/or one type of data relating to the state of the first peripheral.

4. Adaptation method according to claim 2 or 3, characterized in that said digital signal transmission protocol is defined by a condition for sending a digital signal, the condition being chosen from among at least one condition according to which the first peripheral emits data spontaneously according to a recurrence rule, and/or a condition according to which the first peripheral emits data consecutively to a request from the operating system.

5. Adaptation method according to one of the preceding claims, characterized in that one function of at least one first interaction means (22) of the first peripheral (2) is to modify the digital signal associated with at least a second interaction means (21, 23, 24, 25, 26, 27) of the first peripheral when said at least one first interaction means (22) is actuated.

6. Adaptation method according to one of the preceding claims, characterized in that the first peripheral (2) is a manual control peripheral of an information processing machine.

7. Adaptation method according to the preceding claim, characterized in that the first peripheral (2) is a computer mouse or a joystick.

8. Adaptation method according to one of the preceding claims, characterized in that the first peripheral (2) is a computer mouse, and in that the computer mouse comprises at least one button (22), the step transmission comprising the transmission of a first digital signal (S2-13, S2-14, S2-15, S2-16) of the second set (S2) when the at least one button (22) is actuated in combination with translational movement of the mouse on a support in one direction, the emission step comprising the emission of a second digital signal (S2-9, S2-10, S2-11, S2-12) of the second together (S2) when the at least one button (22) is not actuated in combination with a translational movement of the mouse on a support in said direction.

9. Adaptation method according to one of the preceding claims, characterized in that it comprises: - a step (P1) of identifying a second digital peripheral (2') capable of transmitting the second set (S2) digital signals,

- a step (P2) of identifying at least one interaction means (4') of the second peripheral, the second peripheral being capable of transmitting at least one digital signal of said second set following actuation of the other at least one interaction means (4') of the second peripheral,

- a step (P3) of identifying at least one manual gesture allowing a user to actuate said at least one means of interaction (4') of the second peripheral (2'),

- a step (P4) for associating the at least one digital signal said second sub-assembly (S2) to at least one means of interaction (4) of the first peripheral, the at least one means of interaction (4) of the first peripheral being intended to be actuated by said at least one manual gesture allowing a user to actuate said at least one means of interaction (4') of the second peripheral (2') or by a similar gesture.

10. Adaptation method according to the preceding claim, characterized in that it comprises a step (P5) of calculating a number of first interaction means (22) of the first peripheral (2) whose function is to modify the digital signal associated with at least one second interaction means (21, 23, 24, 25, 26, 27) of the first peripheral (2) when said first interaction means (22) are actuated, and/or in this that it comprises a step (P6) of calculating a number of digital signals compatible with the operating system of the second information processing machine (3') for which no means of interaction (4) and/ or combination of means of interaction (4) of the first peripheral (2) is associated.

11. Digital peripheral (2) comprising a set of interaction means (4), a microprocessor (5) and a memory (6), the peripheral being configured to implement the adaptation method according to one of claims previous ones.

12. Computer system (1) comprising an information processing machine (3, 3') and a peripheral (2) according to the preceding claim.

13. Computer program product comprising program code instructions recorded on a computer readable medium to implement the steps of the method according to any one of claims 1 to 10 when said program is running on a computer.

14. Data recording medium, readable by a computer, on which is recorded a computer program comprising program code instructions for implementing the method according to one of claims 1 to 10.