Patent Publication Number: US-2019172448-A1

Title: Method of performing multi-modal dialogue between a humanoid robot and user, computer program product and humanoid robot for implementing said method

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation of U.S. patent application Ser. No. 15/300,226, filed Sep. 28, 2016, which is based on International Application No. PCT/EP2015/058373, filed on Apr. 17, 2015, which is based on and claims priority from European Patent Application No. EP 14305583.8, filed Apr. 17, 2014, the entire contents of which are incorporated herein by reference. 
    
    
     FIELD OF THE INVENTION 
     The invention relates to a method of performing a so-called “multimodal” dialogue between a humanoid robot and a user, or interlocutor, which is usually human. The invention also relates to a computer program product and a humanoid robot for the implementation of such a method. 
     BACKGROUND 
     A “humanoid robot ” can be defined as a robot with certain attributes of the appearance and functionality of a human being such as a trunk, head, arms, legs, the ability to communicate orally with a human being using voice-recognition and vocal synthesis, etc. A robot of this kind aims at reducing the cognitive distance between man and machine. One of the most important characteristics of a humanoid robot is its ability to support a dialogue as natural as possible with a human interlocutor. This capability is essential for the development of “companion robots” to help the elderly, sick or simply lone people in the necessities of daily life, and to provide these people with an acceptable—also from the emotional point of view—substitute to the presence of a human personal assistant. For this, it is essential to develop the ability of such humanoid robots to interact with humans in a way which emulates as closely as possible human behavior. In particular, it is necessary that the robot can interpret questions or statements of the human being, make replicas in conversational mode, with a wealth of expression corresponding to that of a human being and modes of expression that are in synergy with the types of behaviors and emotions that are typically those of a human being. 
     A first step in this direction has been made thanks to the methods of programming Nao™ humanoid robots marketed by the applicant and disclosed in international patent application WO2012/000927 concerning a robot player, and in international patent application WO2012/010451 concerning a humanoid robot with a natural interface dialogue. 
     However, the robots disclosed by these documents can only perform limited and predetermined elements of dialogue. 
     International patent application WO2013/150076 describes a humanoid robot with a conversational agent, voice recognition tools and tools for analyzing the behavior of interlocutors, which shows a richer conversational ability than that of pre-existing robots. 
     SUMMARY OF THE INVENTION 
     The invention aims at improving such a humanoid robot, making interactions with a human interlocutor richer and more realistic. The invention includes, in particular, the project called “Juliette”, which aims at improving human-robot interaction by providing the robot with the ability to interpret the actions of the user. 
     An object of the invention, allowing achieving such a goal, is a method of performing a dialogue between a humanoid robot and at least one user according to claim  1 , comprising the following steps, carried out iteratively by said humanoid robot:
         i) acquiring a plurality of input signals from respective sensors, at least one said sensor being a sound sensor and at least one other sensor being a motion or image sensor;   ii) interpreting the acquired signals to recognize a plurality of events generated by said user, selected from a group comprising: the utterance of at least a word or sentence, an intonation of voice, a gesture, a body posture, a facial expression ;   iii) determining a response of said humanoid robot, comprising at least one event selected from a group comprising: the utterance of at least a word or sentence, an intonation of voice, a gesture, a body posture, a facial expression, said determining being performed by applying a set of rules, each said rule associating a set of input events to a response of the robot;   iv) generating, by said humanoid robot, said or each said event; characterized in that at least some of said rules applied at said step iii) associate a response to a combination of at least two events jointly generated by said user and recognized at said step ii), of which at least one is not a word or sentence uttered by said user.       

     Particular embodiments of such a method constitute the subject-matter of the dependent claims. 
     Another object of the invention is a computer program product comprising program code instructions for executing such a method when said program is executed by at least one processor embedded on a humanoid robot, said robot comprising : a plurality of sensors operatively connected to said or at least one processor and comprising at least one sound sensor and at least one image or movement sensor, to acquire respective input signals; a speech synthesis module controlled by said or at least one said processor to utter words or sentence; and a set of actuators driven by said or at least one said processor enabling said robot to perform a plurality of movements or gestures . 
     Yet another object of the invention is a humanoid robot comprising:
         at least one embedded processor;   a sensor assembly operatively connected to said or at least one said processor and comprising at least one sound sensor and at least one image or movement sensor, to acquire respective input signals;   a speech synthesis module driven by said or at least one said processor to utter words or sentences, and   a set of actuators driven by said or at least one said processor enabling said robot to perform a plurality of movements or gestures; characterized in that said or at least one said processor is programmed or configured to carry out a method according to an embodiment of the invention.       

     Such a humanoid robot may further comprise a device for connection to at least one remote server, said or at least one said processor being programmed or configured to cooperate with said or at least one said remote server to carry out a method according to an embodiment of the invention. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Other features, details and advantages of the invention will become apparent upon reading the following description made with reference to the accompanying drawings given by way of example, wherein: 
         FIG. 1  shows a physical architecture of a humanoid robot suitable for implementing the invention; 
         FIG. 2  is a diagram illustrating the steps of a method according to an embodiment of the invention and an arrangement of hardware and software means for its implementation; 
         FIG. 3  is a diagram illustrating the implementation of a “proactive” dialogue according to one embodiment of the invention; 
         FIG. 4  is a diagram illustrating a step of animating a response of a humanoid robot according to an embodiment of the invention; 
         FIGS. 5 a , 5 b  and 5 c    are three examples of syntactic analysis of sentences for the determination of one or more words to be animated; 
         FIG. 6  illustrates the servo-control of the position of the robot relative to a user according to an embodiment of the invention. 
         FIG. 7  is a diagram illustrating a step of identifying events according to one embodiment of the invention; and 
         FIG. 8  is a diagram illustrating a step of phonetic speech recognition according to one embodiment of the invention. 
     
    
    
     DETAILED DESCRIPTION 
       FIG. 1  displays a physical architecture of a humanoid robot in a number of embodiments of the invention. 
     The specific robot R on the figure is taken as an example only of a humanoid robot in which the invention can be implemented. The lower limb of the robot on the figure is not functional for walking, but can move in any direction on its base RB which rolls on the surface on which it lays. The invention can be easily implemented in a robot which is fit for walking. By way of example, this robot has a height H which can be around 120 cm, a depth D around 65 cm and a width W around 40 cm. In a specific embodiment, the robot of the invention has a tablet RT with which it can communicate messages (audio, video, web pages) to its environment, or receive entries from users through the tactile interface of the tablet. In addition to the processor of the tablet, the robot of the invention also uses the processor of its own motherboard, which can for example be an ATOM™ Z530 from Intel™. The robot of the invention also advantageously includes a processor which is dedicated to the handling of the data flows between the motherboard and, notably, the boards bearing the Magnetic Rotary Encoders (MREs) and sensors which control the motors of the joints in a limb and the balls that the robot uses as wheels, in a specific embodiment of the invention. The motors can be of different types, depending on the magnitude of the maximum torque which is needed for a definite joint. For instance, brush DC coreless motors from e-minebea™ (SE24P2CTCA for instance) can be used, or brushless DC motors from Maxon™ (EC45_70W for instance). The MREs are preferably of a type using the Hall effect, with 12 or 14 bits precision. 
     In embodiments of the invention, the robot displayed on  FIG. 1  also comprises various kinds of sensors. Some of them are used to control the position and movements of the robot. This is the case, for instance, of an inertial unit, located in the torso of the robot, comprising a 3-axes gyrometer and a 3-axes accelerometer. The robot can also include two 2D color RGB cameras on the forehead of the robot (top and bottom) of the System On Chip (SOC) type, such as those from Shenzen V-Vision Technology Ltd™ (OV5640), with a 5 megapixels resolution at 5 frames per second and a field of view (FOV) of about 57° horizontal and 44° vertical. One 3D sensor can also be included behind the eyes of the robot, such as an ASUS XTION™ SOC sensor with a resolution of 0.3 megapixels at 20 frames per second, with about the same FOV as the 2D cameras. The robot of the invention can also be equipped with laser lines generators, for instance three in the head and three in the base, so as to be able to sense its relative position to objects/beings in its environment. The robot of the invention can also include microphones to be capable of sensing sounds in its environment. In an embodiment, four microphones with a sensitivity of 300 mV/Pa+/−3 dB at 1 kHz and a frequency range of 300 Hz to 12 kHz (−10 dB relative to 1 kHz) can be implanted on the head of the robot. The robot of the invention can also include two sonar sensors, possibly located at the front and the back of its base, to measure the distance to objects/human beings in its environment. The robot can also include tactile sensors, on its head and on its hands, to allow interaction with human beings. It can also include bumpers on its base to sense obstacles it encounters on its route. 
     To translate its emotions and communicate with human beings in its environment, the robot of the invention can also include:
         LEDs, for instance in its eyes, ears and on its shoulders;   Loudspeakers, for instance two, located in its ears.       

     The robot of the invention may communicate with a base station or other robots through an Ethernet RJ45 or a WiFi 802.11 connection. 
     The robot of the invention can be powered by a Lithium Iron Phosphate battery with energy of about 400 Wh. The robot can access a charging station fit for the type of battery that it includes. 
     Position/movements of the robots are controlled by its motors, using algorithms which activate the chains defined by each limb and effectors defined at the end of each limb, in view of the measurements of the sensors. 
       FIG. 2  illustrates a method of dialogue according to one embodiment of the invention. Dialogue obtained by the implementation of such a method can be called “multimodal” because the robot takes into account, for formulating its response, a combination of qualitatively different events, such as spoken words, gestures, body attitudes, facial expressions, etc. generated by a user (or interlocutor). It should be noted that the aforementioned international application WO2013/150076 also discloses a method wherein the robot reacts to a gesture—e.g. a waving of the hand—of the interlocutor, but not to a specific combination of jointly-generated verbal and non-verbal events. 
     In a first step i) of the method illustrated on  FIG. 2 , input signals s 1 , s 2  from respective sensors c 1  (a microphone) and c 2  (a camera) are acquired by the robot and processed by bank of extractor modules EXT (here and below, the term “module” is used to indicate a software module run by an embedded processor or by a remote sensor; it should be understood that hardware, or hardware-software hybrid implementations, are always possible and fall within the scope of the invention). Each extractor module receives an input signal, or a plurality of signals of a given type, and outputs information for use by other modules of the robot. For example, in the case of  FIG. 2 , a first extractor module processes the signals s 1  from microphone c 1  to provide 
     a textual output TXT obtained by transliterating sounds identified as compatible with a human voice, and metadata MD representative of an intonation of said voice (happy, sad, angry, imperative, interrogative . . . ); a second and a third extraction module treat signals s 2  from camera c 2  to generate “non-textual data” NTD representative of points of interest, respectively, of a face and of an arm of a user in the field of view of said camera. The output of the bank of extractors modules are provided as inputs to a dialogue engine module, DE. The processing performed by this module can be complex and require access to databases of significant size. For this reason, this processing may be partially performed by one or more remote servers RS, accessed through an Internet connection. 
     The dialogue engine module comprises a recognition module REC which receives as inputs the data TXT, MD, NTD and associates them to predefined “input events” EVI. For example, the module REC may associate textual data TXT to words of a dictionary; also, it may associate a particular configuration of points of interest of a user&#39;s face to a smile, and even attribute a numerical value to said smile (e.g. a value comprised between 0 and 5, wherein 0 means no smile and 5 very large smile); also, it may associate a particular configuration of points of interest of a user&#39;s arm to a gesture, e.g. a waving. Depending on the specific embodiment considered, the tasks of the recognition module can be carried out by the extractor modules—e.g. one may have a “smile extractor”, providing directly a smile value as described above. 
     A “dialogue context” or “topic”, parameter CTX, stored in a memory of the robot, may influence the decisions of the recognition module. Indeed, similar entries can be interpreted as different events depending on the context; for example, in different contexts a wide opening of the user&#39;s mouth can be interpreted as a yawning or an expression of stupor. This corresponds to a second step ii) of the inventive method. 
     A third step iii) of the inventive method is carried out by a “rule application” module RUL which associates a response to an input event, or a combination of input events. The response is constituted by one or more “output events” EVO, which can be words or phrases to be uttered by the robot, sounds to be emitted by it, gestures to be performed by it, expressions of its “face” etc. The above-cited international application WO2012/010451 describes a rule application module which can be used in the present invention, albeit with an important modification. Indeed, according to the present invention, at least some of the rules associate a response not to a single input event, but to a combination of at least two jointly-generated events, of which at least one is non-verbal (i.e. does not consist in the utterance of a word or sentence by the user). According to a preferred embodiment of the invention, at least some of the rules—and particularly some of those taking multiple events as their inputs—determine responses consisting of a combination of output events, of which at least one is non-verbal. 
     For example, a possible rule may be:
         IF {(smile&gt;2) AND [waving or “hallo” or “hi”] } THEN {(smile=4) AND waving AND “hallo”}.       

     This means that if the user smiles with an at least moderate smile and waves his hand or say “hallo” or “hi”, then the robot replies with a large smile, a waving and the utterance of the word “hello”. 
     By “jointly generated” events it is meant two or more events which are sufficiently near in time to be considered simultaneous for the purpose of the dialogue. For example, if a user waves his hand and then, one second later, says “hallo”, the two events are considered to be jointly generated, even if they are not strictly speaking simultaneous. 
     At each time, applicable rules depend on a dialogue context CTX, which in turn is determined by previously applied rules and/or inputs. Rules relating to a same context or topic form a “dialogue”, which can be edited by a programmer as disclosed by international application WO 2011/003628. Examples of dialogue topics might be “football”, “politics”, “cooking”, but also “meeting” when the user initiates the dialogue with the robot (or vice-versa, as it will be explained later) or “bye” when the user leaves or expresses the will of terminating the dialogue. 
     Moreover, at each time, applicable rules may depend on an internal state RIS of the robot, which in turn is determined by previously applied rules and/or inputs. Examples of internal states are “happy”, “sad”, “tired”, but also “battery discharged” or “mechanical failure”. 
     For example, if the robot recognizes that the user has a sad expression, its internal state will become “concerned”. If then the user says “I am not very well today”, the dialogue context will take the value “health” (indicating that health will be the topic of the conversation), determining a set of appropriate rules. 
     It is to be understood that the “generation” of an input event does not necessarily requires an action performed by the user; for example, the fact that the user wears colorful cloths may be an “event”. Rules of a particular class, called “proactive rules”, are applied to determine a response to an event—or combination of events—not including words uttered by the user or identified gestures. In other term, the robot reacts to stimuli such as the number of people present in a room, the expression of a silent user, the color of a cloth, etc. by initiating the dialogue. In a particular embodiment of the invention, some “small talk” topics are labeled as being proactive, which means that all the rules relating to said topics are proactive. An example of “small talk” topic is “smile”, containing rules which are applied when the user smiles without speaking. More specific topics such as “cooking” or “politics” are usually not proactive. 
       FIG. 3  illustrates the implementation of a “proactive” dialogue according to a particular embodiment of the invention. The extractor bank EXT comprises a color extractor COL, recognizing the color of different elements of a scene, a smile extractor SML, an extractor module NBP determining the number of people in a room, a text extractor TXTX and a gesture extractor GST. In a specific situation, the color extractor identifies a red shirt, the smile extractor recognizes a very large smile (smile=5) of the user and the NBP module counts 2 people in the room, while the modules TXTX and GST indicate that the user is neither speaking nor performing a well-identified gesture. The dialogue engine, and more precisely the rule application module RUL, will then search a “proactive” rule applicable to this situation within a subset PRO, containing “small talk” topics, of a dialogue database DDB. 
     The method of  FIG. 2  also comprises an optional step iii-a) of animating a response of the robot, when the latter consists of—or comprises—the utterance of at least a word or sentence. An animation is a sequence of movements of the robot and/or other non-verbal events (e.g. changes of expression) which accompanies its speech, emulating the “body talk” of a human being. An animated response might be indistinguishable from a multimodal response including speech and movements; however, they are produced in different ways. A multimodal response is directly determined by a rule application module, as discussed above; instead, an animation is added to a verbal response by a dedicated module ANE, taking output specific events EVO (namely, verbal events, i.e. words to be uttered) generated by the rule application module as its inputs, as it will be explained below with reference to  FIGS. 4, 5   a ,  5   b  and  5   c.    
     As illustrated on  FIG. 4 , the animation module, or engine, ANE comprises a syntax analysis module SYNTA, an animation list AST stored in a memory embarked on, or accessible by, the robot, and two modules  10 X and FX for computing expressiveness values. An “expressiveness value” is a parameter determining to which extent a movement has to be “theatrical” or “discrete”. An “expressiveness coefficient” defines a modification of an expressiveness value. The term “expressiveness” refers to both expressiveness values and coefficients. 
     Syntax analysis allows, as it will be discussed later with reference to  FIGS. 5 a , 5 b  and 5 c   , to determine the word(s) to be animated and related words which are not animated by themselves but influence the expressiveness of the animated word(s). Moreover, the syntax analysis module may also determine an “overall” expressiveness of the text to be uttered e.g. by taking into account the frequency of “emotional words” in the text and/or the internal state RIS of the robot. Each word to be animated has an expressiveness on its own; this expressiveness is combined with those of the related word and to the overall expressiveness of the text by module  10 X, which outputs an expressiveness value called “one-off expressiveness”. 
     Each word to be animated is also associated to a “concept”. The concept and the one-off expressiveness are used to choose an animation within an animation list ALST. The choice depends on the concept associated to the word and on the one-off expressiveness computed by module  10 X. For example, each animation of the list may be associated to one or more concepts, and have a specific expressiveness value; in this case, the animation associated to the concept expressed by the word to be animated, and whose specific expressiveness value is closest to the one-off expressiveness is selected. In the example of  FIG. 4 , the selected animation is called anim2 and has a specific expressiveness of exp2. Finally, a module FX combines (e.g. averages) the specific expressiveness of the selected animation and the one-off expressiveness to compute a final expressiveness expf. The output of the animation engine is a pair (animation, final expressiveness). The final expressiveness value determines e.g. the speed and/or amplitude of the gestures composing the animation. 
       FIG. 5 a    illustrates the syntactical analysis of a sentence to be animated: “He loves chocolate and beer”. The syntactical tree puts in evidence the conjunction “AND” linking two complements, which indicates an enumeration. In this case, the conjunction is the word to be animated. It is associated with a concept “enumeration”, which in turn is associated with an enumeration called “two”, consisting in a gesture wherein the robot closes his hand, it extends its thumb and then it extends its index. 
       FIG. 5 b    illustrates the syntactical analysis of another sentence to be animated: “I agree with you”. This is a simple sentence with a verb in positive form, a subject and a complement. All the words, except “with” are animated: “I”, by an animation “myself” wherein the robot indicates itself, “agree” with an animation “yeah” wherein the robot nods; and you by a robot. 
     These two examples are very simple ones, wherein expressiveness does not play any role. A more complex example is constituted by the sentence “I strongly disagree with you”, whose syntactical tree is illustrated on  FIG. 5 c   . In this case, the verb is in negative form (semantically, if not grammatically); in such a case, the verb itself is animated, but not the subject and the complement. Moreover, there is an adverb (“strongly”) which emphasizes the disagreement. 
     The verb “disagree” is associated with the concept “disagreement” and has an expressiveness value of 5 on a scale from 0 to 10. The one-offr expressiveness, however, increases from 5 to 8 due to the presence of the adverb “strongly”. In an embodiment of the invention, the internal state RIS of the robot could also alter the one-off expressiveness value. 
     There are three animations associated to the concept “disagreement”: “oppose1” with a specific expressiveness of 3, which only comprise a change of expression of the robot; “oppose2” and “oppose3” with specific expressivenesses of 6 and 9 respectively, which also include gestures. The animation whose specific expressiveness is closes to the one-of expressiveness is “oppose3”, which is then selected. However, its final expressiveness is reduced to 8.5, corresponding to the average of the specific and the one-off expressivenesses. This means that the gestures will be slightly slower and/or less ample than in the “standard” version of “oppose3”. 
     Reverting back to  FIG. 2 , it can be seen that output events and/or animation are used to drive different actuators of the robot to “perform” the response. In the exemplary embodiment of the figure, the actuators are a loud-speaker A 1 , a set of facial expression-controlling actuators A 2  and limb-controlling actuators A 3 . This is step iv) of the method of  FIG. 2 . 
     Even an animated and/or multimodal dialog with a humanoid robot may be perceived as awkward and unnatural if the robot stands by the user and stares directly at him or her. Moreover, if the robot is too close to the user, it may punch him or her while “speaking with its hands” in order to produce an animated or multimodal response. There is also a general risk of the robot falling upon the user in case of dysfunction. For this reason, according to a preferred embodiment of the invention, the robot is servo-controlled to maintain a distance from the user within a predetermined (and possibly context-dependent) range. Advantageously, the distance is measured between a part of the robot, e.g. its waist, and the lower body (up to the waist) of the user: this allows the user to lean toward the robot and touch it with his/her hand without causing it to move back. Advantageously, the robot is also servo-controlled to maintain an orientation with respect to the user within a predetermined (and possibly context-dependent) angular range. Preferably, the robot performs pseudo-random translation and/or rotation movements while remaining within said distance and angular ranges, to avoid the disturbing feeling induced by an unnaturally static robot. 
       FIG. 6  shows the robot R and a user U from above. In a reference frame centered on the robot, it is required that the user—or, more precisely, the user&#39;s lower body—remains in an authorized region AR defined by a distance range [d1 , d2] and an angular range [−Φ,Φ]. If the user moves, the robot also moves to keep this condition satisfied. Moreover, as mentioned above, the robot may perform pseudo-random translation and/or rotation movements while maintaining the user in the authorized region. 
     In order to obtain a “natural” behavior of the robot, the distance and angular ranges may vary during the dialog, depending on the active topic. 
     The position of the user with respect to the robot may be determined by using cameras coupled with image processing modules, laser line generators and/or sonar sensors: see above, the description of the physical architecture of a humanoid robot accompanying  FIG. 1 . 
     Reverting back to  FIG. 2 , it will be noted that step ii) of interpreting input signals to recognize different kinds of events, either verbal or non-verbal, is a very important step of a method according to the invention. Recognizing events means matching input signals to an item of a predetermined list of expected events stored in a memory of the humanoid robot, or accessible by it. Advantageously, said list of expected events is selected, among a plurality of said lists, depending on the dialogue context or topic. 
     For example, speech recognition consists in matching sound signals acquired by sensors with a natural language word, or series of words, of a dictionary, which can be context-specific. Usually, each matching result is associated to a confidence score; the higher this score, the greater the probability of correctness of the matching. Usually, a threshold is used to discriminate between “successful” matching and failed attempts to identify an event. 
     Depending on the particular kind of event to be recognized, several matching methods, of different complexity, are known in the art. For example, in the field of speech recognition the following methods (or, rather, families of methods) are known: 
     Exact matching: this is the simplest, and fastest, method, using a finite state machine to check if an input contains, exactly, a word or sentence. The confidence score is Boolean: either the matching is certain (score=1), or the identification attempt has filed (score=0). 
     Approximate matching: it is also based on a finite state machine, but it allows certain mistakes in the matching chain. The confidence score decreases as the number of mistakes increases. 
     Phonetic matching (for speech recognition only), based on the determination of a phonetic distance between the input and the words, or sentences, of the dictionary. 
     Semantic matching, the most complex method is based on a computation of the distance between the observed vocabulary in the input and the vocabulary in each dialogue entry. The distance is the cosine measure between the vector representation of said input and said entries. The vectors are calculated following a “bag-of-word” distributional semantic representation, using TF-IDF (Term Frequency-Inverse Document Frequency), weighting. 
     Rather than using a single matching method, the robot may use a hierarchical approach, starting from the simplest method, accepting the result if the confidence score exceeds a preset threshold and trying with a more complex method otherwise; if the confidence score obtained using the most complex matching method (e.g. semantic) is still below the threshold, then the search has failed. In this case, the robot either ignores the input or asks for clarification (e.g. by uttering “Sorry, what did you say?”, in case of failed speech recognition). 
     The hierarchy can also be adapted to factors such as the speech recognition technology used. Semantic matching will be preferred when the ASR (Automatic Speech Recognition) is based on large language models, while phonetic matching will help recover errors from less robust embedded ASR results. 
     Advantageously, the robot may select a subset of matching methods depending on different parameters, and in particular on the dialogue context or topic. If the ongoing dialogue is a “closed” one, wherein only a few different inputs are expected, exact matching is likely to work successfully, and is then worth trying. On the contrary, in the case of a very broad context, allowing a large number of possibly input events, it might be preferable to drop exact and approximate marching and to start directly with phonetic or even semantic methods. On the right part of  FIG. 7  it is illustrated a hierarchical chain of matching methods MM 1 -MM 4  of increasing computational complexity. For each matching method, two outcomes are possible: either the matching is successful, in which case an input event EVI is generated, or it is not, in which case the next matching method is tried (except for MM 4 ). The first matching method to be tried is not necessarily MM 1 : it is selected by a matching strategy engine MSE depending on the dialogue context CTX and possibly other parameters. 
     If an internet connection is available, at least the most complex matching method(s) may be carried out by a remote server (see  FIG. 2 ). 
       FIG. 7  refers to the case of speech recognition, taking as input signal a text TXT obtained by transliterating a sound recognized as a human voice by a suitable extractor, but this approach is more general. It will be understood that it is not limited to the case of “multimodal” dialogue. 
     A particular speech-recognition method, based on phonetic matching, will now be described with reference to  FIG. 8 . 
     Sounds acquired by a sensor (microphone) c 1  are provided as inputs to a transcription module TRSC, which converts them into a text. Then, this text is converted into its phonetic equivalent, by taking into account the specificity of the language of the dialogue (which is a parameter determined by the robot e.g. depending on the identity of the user, recognized with the help of a camera and a face recognition module, known in the art), by a phonetic conversion module PHON. Transcription and phonetic conversion could also be performed jointly; together, they constitute what can be called a “phonetic transcription”. 
     Then, the phonetic transcription is simplified and smoothed by a simplifying module SIMP. 
     “Simplifying” consists in representing by a single phoneme different phonemes which are likely to be confused with each other—e.g. “d” and “t” or “k” and “g”. 
     “Smoothing” consists in ignoring the statement segmentation proposed by the transcription module (which lies often at the origin of recognition errors), while retaining the information that has motivated it. To this extent, vowels are ignored, except those at the beginning of each word (as identified by the transcription module) and nasal ones. The expected words contained in an INDEX are subject (advantageously offline) to the same or a similar processing. A distance computing module DIST determines the edit distance between the simplified and smoothed phonetic transcription of the input sound and the simplified as smoothed entries of the index. Then, a selection module SEL selects the entry corresponding to the smallest edit distance. 
     By way of example if the user says, in French “A demain” (i.e. “See you tomorrow”), the phonetic transcription will be “A D  MIN” which is then simplified as “ATMN” (“N” representing a nasal vowel). 
     Edit distance is defined as the minimal number of changes which are necessary to convert a string of letters to another one. For example, the edit distance between ADMN et BDLNS is 3 because three changes are necessary:
         ADMN→BDMN (“A” is changed to “B”);   BDMN→BDLN (“M” is changed to “L”)   BDLN→BDLNS (addition of “S”).       

     The invention has been described by considering specific embodiments which combine multi-modal dialogue, animated speech, servo-control of the robot position and particular methods of event (and more particularly speech) recognition. Although they work best in synergy, these different aspects of the invention can also be implemented independently from each other.