FR2956275A1 - Sound stream diffusion synchronizing method for e.g. mobile telephone, involves determining timing period corresponding to lag to be applied to diffusion of sound stream, where timing delay is determined by diffusion delay and time delay - Google Patents

Abstract

The method involves determining a diffusion delay time of a sound stream on a loudspeaker of an audio source (10). A time delay corresponding to time difference between transmission of the sound stream by the source to a receiving terminal (11), and reception, processing and diffusion of the streams on a loudspeaker of the terminal is measured. A timing period corresponding to lag to be applied to diffusion of the sound stream by the terminal and/or the source is determined, where the timing delay is determined by the diffusion delay and the time delay. Independent claims are also included for the following: (1) a receiving terminal comprising units for establishing a wireless connection with an audio source and diffusing a sound stream transmitted by the source on a loudspeaker (2) an audio source comprising units for transmitting a sound stream to a receiving terminal and diffusing the sound stream on a loudspeaker.

Description

Method for synchronizing a broadcast of a sound and terminal stream using such a method

FIELD OF THE INVENTION The subject of the present invention is a method of synchronizing a broadcast of the same sound stream by at least two terminals. The field of the invention is that of the synchronized diffusion of sound streams. More particularly, the invention relates to the simultaneous broadcast of the same sound stream by at least two mobile phones.

The invention also relates to a terminal adapted to implement the method of the invention. State of the art Current mobile phones have become individual and collective musical listening devices. In the situation of collective listening the level of reproduction of the telephone speaker is rarely sufficient. Indeed, the built-in speakers in the phones are very low because of the particular problems of mass, size and power consumption. As for headphones or headphones, they are very inconvenient to share (one earphone per person, except to have a special adapter "U" to connect two pairs of headphones on the same phone, but even in this case listeners are constrained in their movements). So that the mobile phone is not a very effective music listening system as soon as one is two or more, and even more in a situation of mobility.

To overcome this disadvantage, one of the current solutions is to connect the mobile phone to a portable sound amplification speaker. However, with this type of solution the user is obliged to acquire an additional device to allow a comfortable collective listening of the sound flow emanating from the mobile phone. This additional device has a cost that can be significantly high. In addition, this enclosure has a battery that must be powered at regular intervals by batteries or a specific charger. The charger is specific in that it is provided with special connection means to the enclosure, complementary to a housing for these connection means provided on said enclosure. Thus, because of the limitation of the autonomy of such a speaker, because of the limited energy storage capacity of its battery, the user must regularly think about recharging it with its charger connected to an electrical network so as not to be in a situation of mobility with the only loudspeakers of the telephone in working order. Another solution is to reproduce the sound flow on several phones to amplify it. However, the amplified sound has an unpleasant degradation for users. This degradation comes from the time difference between the flows, which, in all conceivable configurations, is too important. Indeed, to be inaudible, this offset should always remain less than a value of the order of 0.1 seconds. Below this value, the mixing of the two sound streams thickens the resulting sound flow (amplifies), while above this value, the mixing of the two sound streams modifies the resulting sound flow by a delay effect. .

This effect, applying exaggerated and mechanical over the entire sound flow, is an unacceptable degradation for the ear. If two mobile phones connected to the wireless network or mobile phone receive a sound stream from the same source accessed via the Internet (Internet radio, music listening sites), the flow returned by the two phones has a shift of one to several seconds. The main factor of this shift is that the network paths used by each stream are different (principle of packet networks). If the two sound streams are available on each of the two phones (in mp3 for example) and that one tries to launch them simultaneously, one does not obtain two synchronized flows because on the one hand the launching will not have been stalled in sufficient detail, on the other hand the launch time of the phone's player depends on the phone and the player. If the sound stream is available on only one of the telephones and we use the streaming of said stream from one phone to another via a wireless connection (pico-network like Bluetooth® by example), one does not obtain two synchronized streams either, because of the time of encoding / decoding (encoding by the first telephone, decoding by the second). Note that the first phone also performs a decoding to read the stream, which more or less compensates for the decoding time of the second phone, but very rough and random, because the phones have different technical characteristics both hardware and software. A need has arisen to offer users the possibility of listening to the same sound stream broadcast simultaneously on several terminals, such as mobile phones, so as to obtain an amplified sound volume. DISCLOSURE OF THE INVENTION The object of the invention is precisely to meet this need while remedying the major drawback of the techniques described above. For this, the invention proposes a sound flow diffusion method that allows two or more phones to share the simultaneous listening of said sound stream, thus increasing the volume restored and improving the spatialization of sound. Thus, a piece of music present on a phone can be listened to by several people together, under better conditions of sound level and spatialization. To do this, the invention implements an algorithm for finely synchronizing the streams returned on each phone to cancel transmission delays, encoding and decoding. In the two-terminal configuration, the operation of the invention is as follows. A master terminal reads the sound stream (in its memory or on a remote Internet site: radio, online shop), broadcasts it on its own speaker and transmits it to a slave terminal which broadcasts it on its speaker. This transmission is performed by a short-distance wireless network (piconet such as Bluetooth®).

The master terminal measures the delay of broadcasting the sound flow on its own speaker (DE as Transmitter Timeout on the Transmitter). It also measures the delay of broadcast on the speaker of the receiving terminal (DT as Delay Time). This delay time corresponds to the transmission time of the sound flow from the master terminal to the receiving terminal, plus the time of reception, processing and broadcasting of said stream on the speaker of the receiving terminal. To measure these delays DE and DT, before the broadcast of the sound flow itself, the master terminal transmits a single beep to its own speaker and to the remote terminal (multifrequency signal type beep or double beep) and listens to the broadcast of this signal on both speakers, thanks to its own microphone. Once the DE and DT times are measured, the source terminal then applies a delay to the diffusion of the sound flow on its own speaker, called the timing delay (DC). This stall delay is determined so that the broadcast on the speaker of the source is synchronized with the broadcast on the receiver, so by applying the formula DC + DE = DT. In the configuration with three or more terminals, the operation of the invention is similar to the previous case, except that there is not a single delay DT, but as many DT delays as slave terminals. Indeed the terminals are a priori different so they have different technical characteristics. To handle these different DT delays the operation is as follows: - The master terminal beeps to the slave terminals. - Each slave terminal replaces this beep with a specific beep (frequency change according to a random choice), in order to distinguish it from other beeps emitted by other slave terminals. - The delay DT is measured not by the master terminal but by each of the slave terminals. - The master terminal applies an arbitrary DCM stall delay sufficiently high (for example 2s), so that, in all cases, the diffusion on his own speaker is not ahead of that of the slave terminals, but on the contrary always late. - Each slave terminal calculates its own DCE timing delay by listening to the beep sound and applying the formula: DCM + DE = DCE + DT. In summary, therefore, the subject of the invention is a synchronization method in which: an audio source transmits a sound flux to at least one receiving terminal, characterized in that the receiver terminal is interconnected at the source; via a wireless telecommunications network, the sound flow from the source to the terminal, a delay of diffusion of the sound flux on a loudspeaker of the source is determined, a delay time is measured. corresponding to the time difference between the transmission of the sound stream by the source to the terminal, the reception, the processing and the broadcasting of the said stream on a loudspeaker of the terminal, - a setting delay corresponding to a delay to be applied is determined the broadcast of the sound stream by the terminal and / or by the source, this timing being determined according to the diffusion delay and the delay time. Advantageously, the invention is also characterized in that: - a request is issued to pair the terminal with the source, - in the event of a positive evaluation of this request by the source, - the interconnection between the source and the terminal.

Advantageously, the invention is also characterized in that the measurement of the delay of diffusion comprises the following steps: - a reference signal is generated in the form of an acoustic signal, - the signal is diffused on the loudspeaker of the source acoustically generated, - the diffusion delay corresponding to the time elapsed between the diffusion of the acoustic signal and its detection by a microphone of the source is measured. Advantageously, the invention is also characterized in that the measurement of the delay time comprises the following steps: - the reference signal is generated in the form of an electromagnetic signal, - the electromagnetic signal is transmitted from the source to the terminal by the intermediate of the wireless network, - the delay time corresponding to the time elapsed between the moment when the electromagnetic signal is transmitted by the source and the moment when the microphone of the source detects a broadcast of the electromagnetic signal received by the terminal is measured. Advantageously, the invention is also characterized in that - the sound stream from the source to the terminal is transmitted via the network in order to be broadcast on the loudspeaker of said terminal, - at the same time the corresponding timing period is applied the difference between the delay of diffusion and the delay time with the diffusion of the sound flux on the loudspeaker of the source.

Advantageously, the invention is also characterized in that - as soon as the evaluation of at least two pairing requests is positive, - the source transmits to each interconnected terminal the reference signal in electromagnetic form via the network wirelessly, then diffuses on its loudspeaker the electromagnetic signal generated, - each terminal modifies the frequency of the electromagnetic signal and diffuses on its loudspeaker the modified signal, - each terminal measures its delay time corresponding to the time elapsed between the detection of the electromagnetic signal diffused by the source and the detection of the modified electromagnetic signal broadcast by the terminal, - each terminal calculates its own stall delay applied to the diffusion of the sound flux on its own speaker, - this stall delay is a function of the delay time, source delay, and a predetermined dwell time of the source, - this predetermined calibration time obtained by experimentation is determined so that it is greater than the delay time calculated by each terminal interconnected with the source. Advantageously, the invention is also characterized in that - the predetermined staging time is applied to the diffusion of the sound flux on the loudspeaker of the source, - the sound flux is transmitted simultaneously to the terminals interconnected at the source by the intermediate of the wireless network, - the calibration time calculated by each terminal is respectively applied to the broadcast of the sound stream received on the speaker of said terminal. Advantageously, the invention is also characterized in that - the sound stream is diffused on the loudspeaker of the source, - the sound flux is then transmitted from the source to the terminal via the wireless network, - an interface source user has a synchronization slider, - this synchronization slider is configured to allow the application of the stall delay to the broadcast of the sound stream of the source, this stall delay is a function of the delay time.

Advantageously, the invention is also characterized in that the receiving terminal is a mobile telephone or any other communicating device provided with a microphone and a loudspeaker. Advantageously, the invention is also characterized in that the audio source is a mobile phone or any other communicating device provided with a microphone and a loudspeaker. Advantageously, the invention is also characterized in that the wireless telecommunications network is a wireless network of Bluetooth®, Wi-FiTM or WimaxTM type. The invention also relates to a receiving terminal characterized in that it comprises means configured to establish a wireless connection with an audio source and to broadcast on its speaker a sound stream transmitted by the source, to the following the synchronization procedure of the invention. The invention also relates to an audio source characterized in that it comprises means configured to transmit to a receiving terminal a sound flow and to broadcast said stream on its speaker at the end of the synchronization procedure of the invention. BRIEF DESCRIPTION OF THE DRAWINGS The invention will be better understood on reading the description which follows and on examining the figures that accompany it. These are presented as an indication and in no way limitative of the invention. FIG. 1 shows a diagrammatic representation of the various terminals involved in the diffusion synchronization process of a sound flux according to one embodiment of the invention.

FIG. 2 shows a schematic representation of a mobile telephone corresponding to a source emitting the sound flow according to one embodiment of the invention. FIG. 3 shows a schematic representation of a mobile telephone corresponding to the receiver of the sound flux emitted by the source according to one embodiment of the invention.

Figures 4 and 5 show step illustrations showing the operation of the method of the invention according to one embodiment. Figure 6 shows an example of step illustrations of Figure 5 in the form of a time chart.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION In the description, the same reference numerals designate, from one figure to another, identical or functionally similar elements. Figure 1 shows a schematic illustration of a broadcast of a sound stream from a transmitting audio source to receiving terminals 11 through a telecommunications network 12. The audio source 10 comprises connection means 16 to the telecommunications network 12. In general, the source 10 of audio signals may be a communicating walkman equipped with a microphone 17 and an earphone or a speaker 18. In one embodiment, the source 10 is a mobile phone. The terminal 11 is a communicating portable device comprising a microphone 13 and an earphone or a speaker 14. In one embodiment, the terminal 11 is a mobile phone. The terminal 11 may also be any other equivalent mobile device provided with connection means 15 to the telecommunications network 12. The microphone 13 of the terminal 11 and that of the source 10 are energy converters whose sound waves captured cause the vibration of a sensitive membrane which causes the creation of an electrical signal varying at the same rate as the sound flow. These microphones 13 and 17 thus make it possible to pick up the acoustic signals present in their environments. The speaker 14 of the terminal or that of the source 10 are able to restore in acoustic form the received electrical energy, transforming it into mechanical energy imposing a vibratory motion to the ambient air. The loudspeaker 14 may comprise an electromagnet connected to a membrane. The telecommunications network 12 is preferably a wireless network. It can be a wireless LAN based on Bluetooth access technology (registered trademark of Bluetooth® SIG, Inc.), Wi-FiTM or WimaxTM.

During the elaboration of the invention, it appeared that the main technical difficulty to be overcome was to synchronize the sound streams diffused by the source 10 and each terminal 11. In fact, it can be seen that beyond a value of the order of 0.1 seconds, the offset between two identical sound streams deforms the original flow, while below this value the offset thickens the flow without deforming it by increasing the power output of several decibels. Thus, an object of the invention is to apply a synchronization method to the diffusion of the sound flux by the terminal 11 or the source 10 so that the offset between the streams is less than about 0.1 seconds. The example of FIG. 1 shows an embodiment of the method of the invention based on the synchronized "streaming" between the transmitter audio source and one or more receiver terminals 11, via the telecommunications network 12.

In the description, actions are provided to devices or programs, that is to say that these actions are performed by a microprocessor of this apparatus or the apparatus comprising the program, said microprocessor being then controlled by instruction codes recorded in a program. memory of the device. These instruction codes make it possible to implement the means of the apparatus and thus to carry out the action undertaken. FIG. 2 shows a schematic representation of an architecture of the audio source 10. The audio source 10 comprises electronic circuits 20 connected to the radio antenna 16. The role of the circuits is to provide the radio interface between the source 10 and the telecommunications network 12. The source 10 further comprises a microprocessor 21, a program memory 22 and a data memory 23 connected to a bidirectional bus 24. The program memory 22 is divided into several zones, each zone corresponding to a function or a mode of operation of the program of the source 10. Similarly, when an action is given to a program, this action corresponds to the setting implemented by a microprocessor, connected to a memory in which the program is recorded, all or part of the instruction codes forming said program.

Only the areas of the memory most directly relevant to the invention are shown. A zone 25 includes instruction codes for receiving a pairing request from a terminal 11. This pairing request is a request for sharing the sound resources of the audio source recorded in the data memory with said terminal 11. A zone 26 includes instruction codes to develop an interconnection authorization request with said terminal 11 and to indicate said request to the administrator of the source 10.

This authorization request may be a light signal and / or sound whose activation allows the administrator of the source 10 to accept or refuse the connection by pressing for example a preset button. This authorization request can also be a validation menu presented to the administrator of the source 10 via a screen of said source. This menu contains a "yes" type authorization command and a "no" type rejection command. Depending on the command selected, the source 10 refuses or grants the pairing of the terminal 11 to the source 10.

In a variant, the interconnection of the source 10 to any terminal 11 can be performed automatically without the intervention of the administrator of the source 10. In this case, as soon as the source 10 receives from the network 12 a pairing request she does it right. For example, the instruction codes return "success" when the pairing is successful and "failed" when the pairing failed. A zone 27 includes instruction codes to allow or refuse the interconnection between the source 10 and the terminal 11 via the network 12, depending on the result returned by the instruction codes of the zone 26.

An area 28 includes instruction codes for activating a reference signal generator. This generator is intended to emit this reference signal which is a pulse signal (beep or double beep). This reference signal may be a single-frequency sinusoidal signal, or a dual-frequency signal (DTMF, for Dual Tone MultiFrequency or two-tone multi-frequency).

In one embodiment, this reference signal comprises a beep emitted during 0.5 seconds. In one variant, the reference signal is a double beep of one second. The interest of the double beep is to be more easily detectable in a noisy atmosphere. An area 29 includes instruction codes for broadcasting the reference signal in the form of an acoustic signal. A zone 30 includes instruction codes for measuring a diffusion delay DE corresponding to the time difference measured between the moment when the acoustic signal is broadcast and the moment when it is picked up by the microphone 17 of the source 10. An area 31 comprises instruction codes for transmitting the reference signal in the form of an electromagnetic signal S1 to the terminal 11 via the network 12. A zone 32 includes instruction codes for detecting via the microphone 17 any electromagnetic signals. broadcast in its environment. A zone 33 includes instruction codes for evaluating a delay time DT corresponding to the time difference measured between the moment when the electromagnetic signal is transmitted and the moment when it is picked up by the microphone 17 of the source 10.

A zone 34 includes instruction codes for transmitting the sound flow to the terminal 11 via the telecommunications network 12. The instruction codes of the zone 34 are also able to apply a DC stall delay to the diffusion of the flux on the speaker 18 of the source 10 so as to synchronize the sound flow diffused by the terminal 11 to that of the source 10 This DC stall delay is a delay calculated as a function of the diffusion delay DE and the delay time DT. This DC stall delay is intended to compensate for the delay caused by: the duration of transmission of the sound stream from source 10 to terminal 11 via the network 12, the duration of processing of the sound flow by the corresponding terminal the time elapsed between the reception of the stream by the source 10 and its broadcast on the speaker 14 of said terminal, and - the encoding time of the source 10 and the decoding of the terminal 11. When the number of pairing requests received is greater than or equal to two, instruction codes of a zone 35 control the diffusion of the acoustic signal following the diffusion of the electromagnetic signal after a DCM timing delay whose duration is predefined. In this case, the instruction codes of the zone 35 transmit to the terminals 11 an activation command of a synchronization algorithm of said terminals. This command includes in particular a field indicating the duration of the DCM timing delay. FIG. 3 shows a schematic representation of an architecture of the terminal 11. The terminal 11 comprises electronic circuits 40 connected to the radio antenna 15. The role of the circuits is to provide the radio interface between the terminal 11 and the telecommunications network 12. The terminal 11 further comprises a microprocessor 41, a program memory 42 and a data memory 43 connected to a bidirectional bus 44. The program memory 42 is divided into several zones, each zone corresponding to a function or a mode of operation of the terminal 11. Only the areas of the memory most directly relevant to the invention are represented. A zone 45 comprises instruction codes for elaborating and transmitting to the source 10 via the network 12 a pairing request. This pairing request includes in particular a field which indicates the name of the local network 12, another field indicating the communication protocol to be used and another field indicating a resource sharing request message from the source 10. An area 46 comprises instruction codes for receiving from the network 12 the interconnection authorization with the source 10 in response to the pairing request. In case of a negative response to the pairing request, the connection between the source 10 and the terminal 11 is automatically interrupted. A zone 47 comprises instruction codes for activating the determination of a DCE timing delay to be applied to the broadcasting of the sound flux on the loudspeaker 14 of said terminal as soon as the network 12 receives the corresponding activation command. issued by the instruction codes of the zone 35 of the source 10. An area 48 comprises instruction codes for receiving the electromagnetic signal S1 from the network 12. The instruction codes of the zone 48 are also able to transform the received electromagnetic signal S1 into an electromagnetic signal S2 whose frequency is modified, preferably randomly. A zone 49 includes instruction codes for detecting, via the microphone 13, the electromagnetic signal S1 diffused by the source 10. A zone 50 comprises instruction codes for detecting, via the microphone 13, the electromagnetic signal S2 diffused from above. speaker 14 of the terminal 11. A zone 51 includes instruction codes for evaluating the delay time DT corresponding to the time difference measured between the moment when the electromagnetic signal S1 diffused by the source 10 has been detected and the moment when the modified electromagnetic signal S2 broadcast by the terminal 11 is picked up by its microphone 13. A zone 52 includes instruction codes to receive the source 10 sound stream to be broadcast through the telecommunications network 12.

A zone 53 comprises instruction codes for transmitting the received sound stream: immediately, when the terminal 11 has not received from the network the activation command issued by the instruction codes of the zone 35 of the source 10, otherwise by applying a DCE timing delay to the broadcast of the sound stream on the speaker 14 of the terminal 11. This DCE timing delay is calculated according to the delay time DT calculated by the instruction codes of the zone 51 and DCM delays and DE provided by the source 10. Fig. 4 shows an illustration of means embodying an embodiment of the method of the invention. Fig. 4 shows a preliminary step in which the synchronization method of the invention in source 10 is in sleep mode. The method will only be activated when the source 10 has received from the network 12 a pairing request. At a step 61, the source 10 processes the received pairing request to allow or reject it. In general, the pairing of the terminal 11 with the source 10 is the operation that allows two communicating systems to identify themselves, generally for the needs of a lasting relationship of trust. Authorizing pairing allows the source 10 and the terminal 11 to be synchronized with each other so that they can communicate wirelessly.

To initiate the exchange between the terminal 11 and the source 10, any activation of a pairing request by a terminal has a visible effect on the source 10 and said terminal so that the user is informed of the state in which the system has just entered and the need to interact with it following an established pairing procedure. Upon receipt of a pairing request, the source 10 goes into a safe state and reserves the use of its means of communication to the pairing procedure until it is completed or when it is canceled, by an action of the user. The pairing procedures are fairly well known in the state of the art and will not be described. When the answer to the pairing request is negative, the connection between the terminal 11 and the source 10 is interrupted. In the opposite case, the source 10 activates the generation of the reference signal, at a step 62. At a step 63, the source 10 diffuses on its own speaker 18, the reference signal in acoustic format. With its integrated microphone 17, the source 10 detects the signal it has emitted. At a step 64, it measures the diffusion delay DE corresponding to the time elapsed between the triggering of the signal and its detection. This diffusion delay DE thus corresponds to the delay of emission of the sound stream by the source 10. At a step 65, the transmitting source 10 transmits to the receiver terminal 11, the reference signal in electromagnetic form S1 via the network 12 The receiver terminal 11 broadcasts it on its own loudspeaker 14. With its integrated microphone 17, the emitting source 10 detects the diffused electromagnetic signal. At a step 66, the source 10 measures the delay time DT corresponding to the time elapsed between the triggering of sending of the signal and its detection. This delay time DT corresponds to the delay of transmission, reception, processing and diffusion of the sound flow by the terminal 11. At a step 67, the source 10 calculates the timing delay DC to obtain a delay of the emission of the sound of the source 10 relative to that of the terminal 11. The calibration time can be expressed as follows: DC = DTDE.

At a step 68, the source 10 applies the setting delay DC to the diffusion of the sound flow on its own loudspeaker and simultaneously transmits, at a step 69, said sound flow to the terminal 11 via the network 12. When the number of terminals interconnected with the source 10 is at least two, the example of Figure 4 reaches its limits very quickly. Indeed, the source 10 can apply a DC delay delay to its flow. If this delay is adequate for synchronization with one of the terminals it is not necessarily with another. The example of FIG. 5 proposes an embodiment taking into account the case of several terminals interconnected with the source 10. In the example of FIG. 5, it is up to each receiver terminal 11 to calculate its delay delay DC. to apply to the broadcast of the sound stream on its own speaker 14. Figure 5 performs the same steps 60 to 62 of Figure 4. In a step 70, the source 10 triggers a pairing request listening window to that received in step 60. To do this it launches, a countdown timer, whose duration is for example of the order of a few milliseconds, time during which he listens to the waves to ensure that no other terminal 11 issues a pairing request. The source 10 determines, in a step 71, the synchronization mode to be applied at the end of this listening window. The outcome of the listening window can be obtained either when the countdown timer reaches zero or is triggered manually by a user. When no other pairing request is received by the source 10 at the end of the listening window, the source 10 applies, in a step 72, the block of steps shown in dotted lines in FIG. Otherwise, the source 10 transmits, in a step 73, to each interconnected terminal 11 an activation command of the synchronization method of said terminal. At a step 74, the transmitting source transmits to the receiver terminals 11, the reference signal in electromagnetic form S1 via the network 12. At a step 75, the transmitting source diffuses on its own loudspeaker 17 the signal electromagnetic S1. At a step 76 following step 72, the source 10 triggers a countdown counter whose duration equals a previously defined DCM master setting delay. This duration is determined preferably by experimentation. In one embodiment, the duration is determined so that it is greater than the maximum delays observed between two diffusions of a sound flow emanating from the same source, typically two seconds. The duration serves as a time reference for setting the delay of the terminals 11. In other words, this duration is a timing delay to be applied by the source 10 to the diffusion of the sound flow on its own loudspeaker. At the end of this countdown timer, the source 10 diffuses, in a step 77, the reference signal in acoustic form. With its integrated microphone 17, the source 10 detects the signal it has emitted. Then, it measures the diffusion delay DE corresponding to the time elapsed between the triggering of the acoustic signal and its detection. This diffusion delay DE thus corresponds to the delay of transmission of the sound stream by the source 10. This diffusion delay DE is then transmitted to the receiving terminals 11. During this period of the countdown timer, the terminals 11 receive from the network 12, at a step 78, at a given instant, the electromagnetic signal S1 diffused by the source 10. The terminals 11 modify the frequency of the electromagnetic signal S1 received in a new electromagnetic signal S2. In one embodiment, this modification is made randomly by each terminal 11. This modification of the frequency is a discrimination criterion allowing the terminals 11 not to take into account the electromagnetic signals broadcast by the other terminals.

At a step 79, the terminals 11 diffuse on their own loudspeaker the electromagnetic signal S2 modified. Thanks to their integrated microphones 14 the receiving terminals 11 respectively detect, in a step 80 the electromagnetic signal diffused by the source 10 and in a step 81 the electromagnetic signal S2 modified.

At a step 82, each terminal 11 measures the delay time DT corresponding to the time elapsed between the reception of the electromagnetic signal S1 broadcast by the source 10 and the reception of the modified electromagnetic signal S2 broadcast by said terminal 11. At a step 83, each terminal calculates its own delay DCE for obtaining a delay to be applied to the emission of the sound flow by said terminal relative to that of the source 10. The timing delay DCE is the difference between the predefined calibration time DCM , the diffusion delay DE of the source 10 and the delay time DT. At a step 84, each terminal 11 applies the calculated DCE calibration delay to the broadcast of the sound stream received from the network on its own loudspeaker. The source 10 broadcasts the sound stream on its speaker with a delay whose duration is equal to the predefined DCM calibration delay. Then it simultaneously transmits the sound stream to be broadcast to the receiving terminals via the network 12. The receiving terminals broadcast the received sound stream on their speakers with a delay whose duration is equal to the respective DCE calibration time calculated. The invention thus allows several slave phones with the same master phone to broadcast an amplified sound stream of comfortable quality. The example of Figure 5 can be applied to any system using the pico-network protocol. This type of protocol is used in a system using Bluetooth® wireless technology, a small network that allows up to eight devices to communicate with each other, one of them playing the role of master and the others becoming his slaves. Figure 6 shows an illustration of the example of Figure 5 in the form of a time chart. In the example of FIG. 6, at least two receiving terminals 11 are interconnected to the source 10. The source 10 behaves like a master terminal and the receiver terminals 11a and 11b as slaves. At an initialization instant TO, the source 10 transmits to all the interconnected terminals the reference signal, in the form of a first electromagnetic signal S1, via the network 12. At a time Ti the source 10 diffuses on its own speaker 18, the electromagnetic source S1. At a time T10, the source 10 diffuses the reference signal in acoustic form. The interval between the instant Ti and the instant T10 corresponds to the predefined calibration delay DCM. The slave terminal 11a receives from the network, at a time T2, the electromagnetic signal S1. It transforms it into another electromagnetic signal S2 whose frequency is modified. At a time T3, it broadcasts it on its own loudspeaker 14. The slave terminal 11b receives from the network, at a time T4, the electromagnetic signal S1. It transforms it into another electromagnetic signal S3 whose frequency is modified. At a time T5, it diffuses it on its own loudspeaker 14. At a time T6, the slave terminal 11 detects the signal S1 broadcast by the source 10 via its microphone 13. Then it detects at a moment T7 the signal S2 that he himself broadcast on its speaker 14. Finally, it measures the DT delay time corresponding to T7-T6. It then calculates the timing delay DCE to be applied when broadcasting the sound stream on its own speaker. This DCE timing delay is a function of the preset DCM dwell time, the DE broadcast delay of the source 10, and the measured DT delay time. At a time T8, the slave terminal 11b detects the signal S1 diffused by the source 10 via its microphone 13. Then it detects at a time T9 the signal S3 which it has itself broadcast on its loudspeaker. Finally, it measures the delay time DT corresponding to T9-T8. It then calculates the timing delay DCE to be applied when broadcasting the sound stream on its own speaker.

This chronological sequence of the different actions of the speakers is only an example of illustrations. Indeed, the signal S1 can be received by the slave terminals 11 before it is broadcast by the source 10. Each speaker then independently executes his own actions successively according to the instruction codes of his program memory. The duration of the predefined DCM timing delay must be determined so large that the microphone 17 of the source 10 detects the acoustic signal broadcast by its own speaker 18 after each paired terminal has calculated its own timing delay DCE. In the opposite case, the sound flux diffused by the source 10 and the terminals 11 has a perceptible dissonance to the ear. In one embodiment, when the delay time DT measured by a terminal 11 is greater than the predefined timing delay DCM, said terminal develops and transmits to the source 10 an error code. The source 10 transmits a reset command of the synchronization activation with a new DCM timing delay whose duration will be increased for example by at least 0.5 seconds. The terminals 11 receiving this command resumes the calculation of their DCE timing delay. In a variant, it can be envisaged that each terminal having finished determining its DCE timing delay sends an end of treatment signaling to the source 10. If the source 10 receives a signaling after the predefined DCM calibration delay, then it transmits a command to reset the activation of synchronization with a new DCM timing delay whose duration will be increased for example by at least 0.5 seconds. Terminals receiving this command will start calculating their DCE stall delay with the new DCM stall delay. Because the delay time DT is almost constant for each terminal, it is not necessary to restart the procedure for calculating this delay. The method of the invention is software that can be implemented as an application to be downloaded to the terminal 11 and the source 10. In this case, the application controls the execution of the instruction codes of the program memory by assuring Job management, I / O operations on devices, allocation of resources to different processes, access to program libraries and files, and job accounting. In one embodiment, the software of the method of the invention is downloaded to the terminal 11 after its manufacture. In this case, the network operator makes available to the user an application corresponding to the software of the method of the invention to download. This provision can be an SMS sent by the operator to the terminal 11 and the source 10 and having a link for downloading the application from a source of said operator. This provision can be a download link of the application accessible from the operator's website. By clicking on this download link, the user can install the method of the invention on the terminal 11 and the source 10. In a variant, the software is integrated in the terminal 11 and the source 10 at the time of its manufacture. The invention makes it possible to synchronize the sound fluxes diffused by the source 10 and the terminals 11 so that the phase shift of the fluxes is less than one-tenth of a second.

Once this synchronization ensured, we can imagine several different configurations: - multiply the flow (by duplicating it on each phone), - separate the stereo stream on 2 phones, each managing a channel, - separate the stream on 3 phones, 1 channel left, 1 right channel, 1 channel mixed (possibly with a low-pass filter, if the speaker is appropriate), - separate the stream on 5 phones (from an original stream 5.1) .... The invention is not limited to the embodiments described above. In particular, synchronization can be done manually. To do this, the transmitting source performs the pairing of at least one receiving terminal. Then, it diffuses in the form of an electromagnetic signal the sound flow on its own loudspeaker and then transmits said signal to the receiving terminal via the network 12. As a result, the duration of the diffusion delay DE of the source 10 is considered like almost zero. There is therefore an offset between the fluxes restored by the source 10 and the terminal 11. This offset is due to the delay time DT. The user interface of the application of the method of the invention on the source displays a synchronization cursor. This synchronization slider may, for example, be of the same ergonomics as the volume slider. This synchronization slider makes it possible to apply a delay to the stream diffused on the source 10 (for example 0 to 0.5s). This delay corresponds to the DC timing delay. The user can then, by acting on the slider, adjust the flow synchronization for optimal listening. In a preferred example, the resolution of the cursor with respect to the delay is preferably of the order of two maximum seconds. The manual synchronization variant can also be applied in a simplified configuration where there is no master terminal or piconet, but all terminals read the same sound stream on a remote site accessed via the Internet. The manual synchronization proposed by the invention makes it possible to correct the delay problems that may arise during the broadcast by each terminal of a sound stream emanating from the same audio source. It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit or scope of the invention. Thus, the present invention is intended to cover the modifications and variations of the present invention provided that they fall within the scope of the appended claims and their equivalents.

Claims (14)

CLAIMS1 - Method for synchronizing a broadcast of a sound stream, in which - an audio source (10) transmits a sound stream to at least one receiving terminal (11), characterized in that - the terminal (61) is interconnected receiver at the source, - the transmission of sound from the source to the terminal is transmitted via a wireless telecommunications network (12), - a delay of diffusion (DE,) of the sound flux on a high - source speaker, - a delay time (DT) is measured corresponding to the time difference between the transmission of the sound stream by the source to the terminal, the reception, the processing and the broadcasting of said stream on a loudspeaker of the terminal, - a setting delay (DC, DCE, DCM) corresponding to a delay to be applied to the broadcasting of the sound flux by the terminal and / or by the source is determined, this setting delay being determined as a function of the delay of broadcast and delay time. 2 - Method according to the preceding claim, characterized in that: - it sends (60) a pairing request from the terminal to the source, - in case of positive evaluation of this request by the source, - it allows interconnection between the source and the terminal. 3 - Method according to one of the preceding claims, characterized in that the measurement of the delay of diffusion comprises the following steps: - one generates a reference signal (62) in the form of an acoustic signal, - it diffuses on the top speaker of the source the acoustic signal generated, - one measures (63) the diffusion delay corresponding to the time elapsed between the diffusion of the acoustic signal and its detection by a microphone of the source. 4 - Process according to the preceding claim, characterized in that the measurement of the delay time comprises the following steps: - the reference signal is generated (65) in the form of an electromagnetic signal, - the electromagnetic signal of the source is transmitted at the terminal via the wireless network, - the delay time corresponding to the time elapsed between the moment when the electromagnetic signal is transmitted by the source and the moment when the microphone of the source detects a broadcast of the received electromagnetic signal is measured. by the terminal. 5 - Process according to claims 3 to 4, characterized in that: - the sound stream is transmitted from the source to the terminal via the network for broadcasting on the speaker of said terminal, - simultaneously we apply the stall delay corresponding to the difference between the broadcast delay and the delay time to the broadcast of the sound stream on the speaker of the source. 6 - Process according to claim 3, characterized in that: - as soon as the evaluation (71) of at least two pairing requests is positive, - the source transmits (74) to each interconnected terminal the reference signal under electromagnetic form (Si) via the wireless network, then diffuses on its speaker the electromagnetic signal generated, - each terminal modifies (78) the frequency of the electromagnetic signal and diffuses (79) on its loudspeaker the signal (S2) modified, - each terminal measures its delay time (DT) corresponding to the time elapsed between the detection of the electromagnetic signal broadcast by the source and the detection of the modified electromagnetic signal broadcast by the terminal. 7 - Method according to the preceding claim, characterized in that: - each terminal calculates its timing delay (DCE) to be applied to the diffusion of the sound flow on its own speaker, - this timing is dependent on the delay time delay , the source diffusion delay and a predetermined timing delay (DCM) of the source, - this predetermined calibration time obtained by experimentation is determined so that it is greater than the delay time calculated by each terminal interconnected with source. 8 - Process according to the preceding claim, characterized in that: - the predetermined stalling time is applied to the diffusion of the sound flux on the loudspeaker of the source, - the sound flux is transmitted simultaneously to the terminals interconnected at the source by via the wireless network, - the calibration time calculated by each terminal is applied to the broadcast of the sound stream received on the speaker of said terminal. 9 - Method according to one of claims 1 to 2, characterized in that: - the sound stream is broadcast on the speaker of the source, - then transmits the sound flow from the source to the terminal through the wireless network, - a user interface of the source includes a synchronization slider, - this synchronization slider is configured to allow the application of the stall delay to the broadcast of the source sound stream, this stall delay is function of the delay time. 10 - Method according to one of the preceding claims, characterized in that the receiving terminal is a mobile phone or any other communicating device provided with a microphone and a speaker. 11 - Method according to one of the preceding claims, characterized in that the audio source is a mobile phone or any other communicating device provided with a microphone and a speaker. 12 - Method according to one of the preceding claims, characterized in that the wireless telecommunications network is a wireless network type Bluetooth®, Wi-FiTM or WimaxTM. 13 - receiving terminal (11) characterized in that it comprises means configured to establish a wireless connection with an audio source (10) and to broadcast on its speaker a sound stream transmitted by the source, to from a synchronization procedure according to one of the preceding claims. 14 - audio source (10) characterized in that it comprises means configured so as to transmit to a receiving terminal (11) a sound flow and to broadcast said stream on its speaker at the end of a synchronization procedure according to one of the preceding claims.