DE10141493A1 - Mobile telephone with adaptive loudspeaker volume regulation dependent on measured signal level of acoustic input signals - Google Patents

Abstract

The mobile telephone (1) has a microphone (2) for reception of acoustic input signals (10) and a loudspeaker (6) for provision of acoustic output signals (15), with measurement of the signal level of the acoustic input signals for corresponding adjustment of the volume level of the acoustic output signals, e.g. by adjusting the amplification factor of a variable amplifier under control of a fuzzy logic (4). An Independent claim for a method for adjusting the volume of acoustic output signals at a mobile telephone is also included.

Description

The invention relates to mobile phones. In particular The invention relates to the volume adjustment of a a built-in speaker phone.

When making a call using a mobile phone, loud noises can occur Ambient noises cause the interlocutor only is difficult to understand. For example, leads louder Traffic noise significantly affects the Call quality. Most cell phones are off therefore variable volume settings of the built-in Speaker provided. The volume setting must however, by the user of the mobile phone itself Ambient noise can be adjusted.

Another problem related to the use of cell phones also on the integrated in a mobile phone Speaker. Through the speaker next to the Voice signals also output call or alarm signals with which for example, an incoming call is announced. The The volume of the call or alarm signals can be adjusted for most User can also set cell phones. Provided this is desired, the volume of the call or Alarm signals, however, also from the user Circumstances are individually adjusted. For example, it is called perceived annoying when a cell phone in closed rooms sends out loud call or alarm signals, although that For example, a cell phone lies open on a desk. On the other hand, items such. B. Garments, which cover the surface of the cellphone, cause the call or alarm signals due to acoustic damping difficult to be noticed.

The object of the invention is therefore a To create communication terminal, in particular a mobile phone, which in is able to independently control the volume of its speaker the respective circumstances, especially the Ambient noise.

The problem underlying the invention is solved by the features of the independent claims. Advantageous further developments and refinements are in the Subclaims specified.

A communication terminal according to the invention has Microphone for receiving acoustic input signals and one Loudspeaker for sending acoustic output signals. Of The communication terminal further comprises first means, which measure the levels of the acoustic input signals, and second means, which are the levels of the acoustic output signals to adjust. An essential idea of the invention is that the Setting the level of the acoustic output signals in Dependence on the levels of the acoustic input signals.

The term "level" is used in the present Patent application, for example, the amplitude of the signal in question meant. However, it can also be the mean a signal amplitude within a certain period of time or a value calculated from the signal amplitude.

A major advantage of the invention is that the communication terminal is able to independently Level of acoustic output signals depending on the Adjust levels of acoustic input signals. For example can this basic idea be designed such that the Communication terminal in the event of loud ambient noise Loudspeaker volume setting increased. This leads for the user of the communication terminal improved acoustic intelligibility of his interlocutor. Furthermore, the communication terminal according to the invention can also be designed so that it is the volume of the measures call or alarm signals sent to him and from this the optimal volume of the call or to be sent Alarm signals determined.

According to an advantageous embodiment of the invention the second means an amplifier unit for adjustment of a gain factor. The gain factor gives that Gain on, with which the acoustic output signals output to the speaker. They also include second means a unit for generating a Gain change signal. The gain change signal specifies a change in the gain factor and is in Dependence on the levels of the acoustic input signals and the set gain factor. This advantageous embodiment gives a simple Realization possibility to adjust the level of the acoustic output signals accordingly to set the ambient noise as best as possible.

Advantageously, the invention Communication terminal a fuzzy logic, which for the setting the level of the acoustic output signals is used. The Principles of fuzzy logic are in issue 3/1993 of Journal of "Spectrum of Sciences", Spectrum Academic publishing house, Heidelberg, 1993 on pages 90 to 103 explained. This section is hereby incorporated into the Disclosure content of the present patent application added.

One advantage of fuzzy logic is that it is easy to use Communication terminal can be integrated because it has little Storage space and computing capacity required and also is easy to program. The one for fuzzy logic necessary arithmetic operations can due to the small Computing needs, for example, one already for other tasks provided computing unit of the communication terminal additionally be transmitted.

The essential features of fuzzy logic are the so-called linguistic variables. Your values are words and Expressions of a natural language. Because words are not as precise as Numbers are defined by the linguistic variables represents fuzzy amounts. The linguistic variables the integrated in the present communication terminal Fuzzy logic are advantageously the levels of the Acoustic input signals, the gain factor and that Gain change signal.

A further development of systems with fuzzy logic represent neuro-fuzzy systems. Pure fuzzy logic systems consist essentially of predetermined linguistic Rules and are therefore not capable of learning. On the other hand, can Learn neural networks from data. A combination of neural Networks and fuzzy logics make it possible to use neuro-fuzzy systems to create fuzzy rules from data as well Learn fuzzy sets. This is usually the learning process of the neuro-fuzzy system initialized with previous knowledge. The present communication terminal can advantageously be a contain such a neuro-fuzzy system.

A particularly advantageous embodiment of the invention provides before that the second means depending on the level of in ambient noise contained in the acoustic input signals adjust the levels of the acoustic output signals. For example, it can be provided that the first means during a period in which no speech signals are transmitted measure the levels of ambient noise and the second means based on the levels of ambient noise and one Reference value for the levels of ambient noise levels optimally set the acoustic output signals. alternative can also be provided that the second means that of the first means measured level of ambient noise compare with the levels of the speech signals and use the Difference between the two levels and a reference value for the Set the difference between the levels of the acoustic output signals.

Another particularly advantageous embodiment of the Invention is characterized in that call or alarm signals are emitted with the acoustic output signals and from the microphone can be received again. The first means determine yours from the received call or alarm signals Level and the second means represent based on the determined Level of the call feedback fed back into the communication terminal or alarm signals the level of the call or to be sent Alarm signals optimal.

This measure can be particularly advantageous when used of the communication terminal according to the invention in a loud Environment. To give the user the call or alarm signals audible output despite the loud ambient noise the communication terminal the volume of itself transmitted call or alarm signals in connection with the Ambient noise and can be the result of such measurements Volume of the call or subsequently to be sent For example, increase alarm signals in a noisy environment. A The volume of the call or alarm signals is increased also according to the invention, if for example Clothing cover the speaker of the communication terminal and acoustic attenuation of the call or alarm signals cause. In the opposite case, assume that the user is in a silenced room. There the call sent by the communication terminal or alarm signals are not caused by ambient noise impaired, so that the communication terminal according to the invention Calls or alarm signals with only a low volume.

According to a further advantageous embodiment of the Invention, the second means provide the level of the signals to be transmitted Call or alarm signals such that the level of through the microphone received call or alarm signals on one predetermined value is regulated. For example be provided that the first call or Alarm signal is used to check the level of the again received call or alarm signal the levels of the other call or set alarm signals. It is special advantageous if the first call or alarm signal with only a low volume is emitted so that it is in a quiet environment for the user of the associated Communication terminal is not perceived as disturbing.

The communication terminal according to the invention can be advantageously as a mobile phone or as a handset cordless phone or as an integral part of a PDAs (Personal Digital Assistant) or a laptop realize.

A method according to the invention for adjusting the level of Acoustic output signals in a communication terminal includes the following steps. First of all Acoustic input signals are received and their levels are measured. Then the level of the Acoustic output signals depending on the levels of the Acoustic input signals.

The method according to the invention is advantageous in optimal setting of the volume of both by means of a Loudspeaker output acoustic voice signals as well the call or alarm signals.

The invention is described below with reference to the Drawings explained in more detail. In these show:

Fig. 1 is a schematic diagram of a first embodiment of the communication terminal according to the invention with an integrated fuzzy logic;

Fig. 2 is a diagram for explaining the operation of the first embodiment; and

Fig. 3 is a schematic diagram of a second embodiment of the communication terminal according to the invention with means for adjusting the volume of the call or alarm signals.

In Fig. 1 a mobile telephone 1 is schematically illustrated that acoustic input signals 10 receives, via a microphone 2 and acoustic output signals 15 emits a speaker unit 6. The received input signals 10 are processed further in the mobile telephone 1 . A processing unit 3 determines an effective amplitude 11 of the input signals 10 within a predetermined time interval. For example, the maximum amplitude within the time interval can be used for this, or the input signals 10 are averaged over the time interval and the effective amplitude 11 is calculated from the mean value by suitable arithmetic operations.

The aim of determining the effective amplitude 11 of the input signals 10 is to determine the volume of the ambient noises which act on the microphone at the time of using the mobile telephone. In order to determine, for example, the ambient noises during a time interval in which the ambient noises are not superimposed by speech signals from the user of the mobile telephone, a suitable signal analysis can be carried out in the processing unit 3 , in order to be able to distinguish between speech signals from the user and pure ambient noises.

The effective amplitude 11 of the input signals 10 is forwarded to a fuzzy unit 4 , the task of which is to determine the optimal gain factor 13 on the basis of the effective amplitude 11 and a set gain factor 13 . The amplification factor 13 serves to amplify signals 14 which are converted into the acoustic output signals 15 in the loudspeaker unit 6 . In order to determine the optimal gain factor 13 , the fuzzy unit 4 is supplied not only with the effective amplitude 11 but also with the respective set gain factor 13 by a processing unit 5 which sets the gain factor 13 . In order to be able to set the amplification factor 13 , the fuzzy unit 4 feeds the processing unit 5 with an amplification factor change signal 12 , which specifies to what extent the amplification factor 13 valid at the respective time should be changed.

The fuzzy unit 4 uses fuzzy logic to determine the gain change signal 12 . The linguistic variables of the present fuzzy logic are the effective amplitude 11 , the gain change signal 12 and the gain factor 13 . According to the principles of fuzzy logic, the effective amplitude 11 as a linguistic variable contains terms in its value set which can be, for example, "very quiet", "quiet", "normal", "loud" and "very loud". The amplification factor 13 has a value set consisting of the terms "large negative", "small negative", "zero", "small positive" and "large positive". The set of values of the gain change signal 12 includes the terms "strongly negative", "somewhat negative", "zero", "somewhat positive" and "strongly positive". A mapping table for the three linguistic variables is listed below. Effective amplitude 11

On the basis of the above assignment table, the amplification factor change signal 12 can be determined from the effective amplitude 11 and the amplification factor 13 .

In FIG. 2, the effective amplitude 11, the gain change signal 12, and the amplification factor of 13 against time t. The curves shown in FIG. 2 result from a simulation of the fuzzy unit 4 shown in FIG. 1 together with the above assignment table. The effective amplitude 11 is given as an input variable of the simulation as a triangular curve. This results in the amplification factor change signal 12 and the amplification factor 13 , an additional time delay being provided between the effective amplitude 11 and the amplification factor 13 .

FIG. 3 shows a schematic block diagram of a second exemplary embodiment of the communication terminal according to the invention. In the second exemplary embodiment, a processing unit 3 , a control circuit 7 and a controller 9 are connected in a mobile telephone 1 between a microphone 2 and a loudspeaker unit 6 . As in the first exemplary embodiment shown in FIG. 1, the processing unit 3 determines the effective amplitude 11 of the input signals 10 . In the present second exemplary embodiment, the effective amplitude 11 is determined from call or alarm signals which are received with the input signals 10 . The call or alarm signals are generated beforehand with a signal generator 8 , forwarded to the controller 9 by means of a signal 16 and amplified there. The call or alarm signals are then forwarded to the loudspeaker unit 6 by means of a signal 18 and output by the loudspeaker unit 6 as output signals 15 . The effective amplitude 11 of the call or alarm signals fed back via the air interface is compared by the control circuit 7 with the levels of the call or alarm signals generated by the signal generator 8 and / or a predetermined reference level. Depending on the ambient conditions of the mobile telephone 1 , the control circuit 7 sets the controller 9 by means of a control signal 17 such that the effective amplitude 11 of the feedback call or alarm signals assumes an optimal value.

Claims (20)

1. Communication terminal ( 1 ) with
a microphone ( 2 ) for receiving acoustic input signals ( 10 ),
a loudspeaker ( 6 ) for emitting acoustic output signals ( 15 ),
first means ( 3 ) for measuring the levels ( 11 ) of the acoustic input signals ( 10 ), and
second means ( 4 , 5 ; 7 , 8 , 9 ) for setting the levels of the acoustic output signals ( 15 ) as a function of the levels ( 11 ) of the acoustic input signals ( 10 ). 2. Communication terminal ( 1 ) according to claim 1, characterized in that the second means ( 4 , 5 ) an amplifier unit ( 5 ) for setting an amplification factor ( 13 ) the level of the acoustic output signals ( 15 ) and a unit ( 4 ) for generating a Gain change signal ( 12 ), the gain change signal ( 12 ) depending on the levels ( 11 ) of the acoustic input signals ( 10 ) and the set gain ( 13 ) is generated and the gain change signal ( 12 ) causes a change in the gain ( 13 ). 3. Communication terminal ( 1 ) according to claim 1 or 2, characterized in that the second means ( 4 , 5 ) have fuzzy logic. 4. Communication terminal ( 1 ) according to claim 3, characterized in that the level ( 11 ) of the acoustic input signals ( 10 ), the amplification factor ( 13 ) and the amplification factor change signal ( 12 ) are linguistic variables of the fuzzy logic. 5. Communication terminal ( 1 ) according to one or more of the preceding claims, characterized in that the second means ( 4 , 5 ) is designed such that it the levels depending on the level ( 11 ) of ambient noise contained in the acoustic input signals ( 10 ) the acoustic output signals ( 15 ). 6. Communication terminal ( 1 ) according to one or more of the preceding claims, characterized in that the second means ( 4 , 5 ) have a neuro-fuzzy system. 7. Communication terminal ( 1 ) according to claim 1, characterized in that the acoustic output signals ( 15 ) comprise call or alarm signals. 8. Communication terminal ( 1 ) according to claim 7, characterized in that the second means ( 7 , 8 , 9 ) are designed such that the level of the call or alarm signals depending on the level of the microphone through the second means ( 7 , 8 , 9 ) feedback ring or alarm signals is adjustable. 9. Communication terminal ( 1 ) according to claim 8, characterized in that the second means ( 7 , 8 , 9 ) are designed such that the level of the call or alarm signals is set such that the level ( 11 ) of the microphone ( 2 ) in the second means ( 7 , 8 , 9 ) fed back call or alarm signals is regulated to a predetermined value. 10. Communication terminal ( 1 ) according to one or more of the preceding claims, characterized in that the communication terminal ( 1 ) is contained in a mobile phone or a mobile part of a cordless telephone or a PDA or a laptop. 11. A method for setting the levels of acoustic output signals ( 15 ) in a communication terminal ( 1 ), comprising the following steps: 1. receiving acoustic input signals ( 10 ); 2. measuring the levels ( 11 ) of the acoustic input signals ( 10 ); and 3. Setting the levels of the acoustic output signals ( 15 ) depending on the levels ( 11 ) of the acoustic input signals ( 10 ). 12. The method according to claim 11, characterized in that in step ( 3 ) an amplification factor ( 13 ) for the levels of the acoustic output signals ( 15 ) is set, wherein for the adjustment of the amplification factor ( 13 ) an amplification factor change signal ( 12 ), which is a change of the gain factor ( 13 ), depending on the levels ( 11 ) of the acoustic input signals ( 10 ) and on the respective size of the gain factor ( 13 ). 13. The method according to claim 11 or 12, characterized in that the step ( 3 ) is based on a fuzzy logic. 14. The method according to claim 13, characterized in that the levels ( 11 ) of the acoustic input signals ( 10 ), the amplification factor ( 13 ) and the amplification factor change signal ( 12 ) are linguistic variables of the fuzzy logic. 15. The method according to one or more of claims 11 to 14, characterized in that the levels of the acoustic output signals ( 15 ) are set as a function of the level of ambient noise contained in the acoustic input signals ( 10 ). 16. The method according to one or more of claims 11 to 15, characterized in that step ( 3 ) is based on a neuro-fuzzy system. 17. The method according to claim 11, characterized in that the acoustic output signals ( 15 ) comprise call or alarm signals. 18. The method according to claim 17, characterized in that the level of the call or alarm signals ( 15 ) to be emitted is set as a function of the level ( 11 ) of the call or alarm signals received with the acoustic input signals ( 10 ). 19. The method according to claim 18, characterized in that the level of the call or alarm signals ( 15 ) to be emitted is set such that the level ( 11 ) of the call or alarm signals received with the acoustic input signals ( 10 ) is regulated to a predetermined value , 20. The method according to one or more of claims 11 to 19, characterized in that the communication terminal ( 1 ) is contained in a mobile phone or a mobile part of a cordless telephone or a PDA or a laptop.