WO2002062040A2

WO2002062040A2 - Telecommunication appliance comprising an acoustic signal generator and a tactile signal generator

Info

Publication number: WO2002062040A2
Application number: PCT/DE2002/000241
Authority: WO
Inventors: Markus Andert; Frank Blaimberger; Walter Engl; Bernd Holz Auf Der Heide; Christine Kocourek
Original assignee: Siemens Aktiengesellschaft
Priority date: 2001-02-01
Filing date: 2002-01-24
Publication date: 2002-08-08
Also published as: WO2002062040A3; DE10104538A1

Abstract

The invention relates to a telecommunication appliance comprising an acoustic signal generator (6) and a tactile signal generator (5). At least the tactile signal generator (5) can be optionally actuated for signalling an incoming call. A device for measuring an applied acoustic pressure is connected to a microphone (8). The tactile signal generator (5) is actuated according to the measured acoustic pressure.

Description

description

Telecommunication device with an acoustic and a tactile signal transmitter

The invention relates to a telecommunication device with an acoustic and a tactile signal transmitter.

Modern mobile telecommunication devices, which can be carried in a pocket on the body by their users, are increasingly being equipped with a tactile signaling device, in addition to the traditional acoustic signaling device for signaling an incoming call, which enables a user to sense movement of the tactile signaling device also perceive the arrival of a call when he, e.g. due to strong ambient noise or because the acoustic signal of the telecommunication device is severely dampened by surrounding clothing, the latter is ignored.

Such a tactile signal generator can e.g. can be realized by a suspension of the rechargeable battery that can be excited to vibrate inside such a telecommunication device. Since the accumulator makes up a large part of the weight of such devices, its vibration leads to a clearly perceptible movement relative to the rest of the device.

In conventional mobile telecommunication devices, such a tactile signal transmitter has to be switched on or off several times a day, depending on the situation, which many users find uncomfortable or annoying. In addition, the need for manual activation of the tactile signal transmitter results in two problem situations, firstly if the ready circuit is forgotten, so that only an acoustic call signal can be generated and a call is not perceived by the user because the call signal is overheard, to whose, if the user forgets to switch off the readiness of the tactile signal transmitter again and the telecommunication device is placed open on a table. In this case, the movement of the tactile signal generator can lead to an inappropriately loud noise, which can often be particularly embarrassing for the user precisely because he has previously activated the tactile signal generator in order to be able to hear incoming calls without anyone else be bothered by it. In extreme cases, the movement of the tactile signal generator can also cause the device on the table to move, fall and be damaged.

The object of the present invention is to provide a telecommunication device with an acoustic and tactile signal transmitter, in which the two types of problem situations set out above can be reliably avoided without the user having to constantly switch between readiness and non-readiness of the tactile signal transmitter.

This object is achieved by a telecommunication device with the features of claim 1.

By measuring the sound pressure applied to the microphone necessarily present in the telecommunication device, it can be determined whether the device is in a loud or quiet environment and, depending on the measured volume, the telecommunication device is able to decide whether on arrival of a call the tactile signal transmitter is activated or not.

Expediently, the acoustic signal transmitter can be switched off coupled to the actuation of the tactile signal transmitter, so that in a quiet environment in which a loud acoustic radio signal can be disruptive, the device only alerts the user of an incoming call by means of the tactile signal transmitter. In a particularly preferred embodiment of the telecommunication device, it is surprisingly provided that the device for measuring the sound pressure carries out the measurement while the acoustic signal transmitter is running. In this case, an assessment of the ambient noise level is of course excluded. However, what can be assessed is the ratio of the sound pressure recorded by the microphone to that generated by the acoustic signal generator. If this ratio is large, it can be concluded that the path of the sound from the acoustic signal generator to the microphone is largely free, for example because the device is placed on a table or other furniture. If the ratio is low, this indicates a strong damping of the sound on the way from the acoustic signal generator to the microphone, which allows the conclusion that the device may be in a pocket for trousers or jackets. In the former case, the telecommunication device switches off the readiness of the tactile signal transmitter in order to avoid the second problem situation described above; in the second case it turns on the tactile signal generator to ensure that an incoming call is perceived by the user.

The limit value for the switchover of the tactile signal transmitter is expediently specified by the manufacturer of the telecommunication device. In addition, the possibility can be provided for a user to adjust this limit value to suit his personal needs.

The measurement of the sound pressure is expediently carried out whenever the acoustic signal generator begins to generate a call signal as a result of the arrival of a call.

The acoustic signal generator is advantageously designed to generate a call signal with increasing volume when a call arrives. This enables the Measurement of the sound pressure still to be carried out at a low volume of the call signal, so that the activation of the tactile signal generator and, if appropriate, a deactivation of the acoustic signal generator can take place even before the acoustic call signal has reached a volume which is disturbing for surrounding persons.

In order to keep disturbances in the measurement of the sound pressure due to ambient noise to a minimum, it is expedient if the device for measuring the sound pressure comprises a filter which is matched to the frequency spectrum of the acoustic signal transmitter. The narrower the spectrum and the pass band of the filter, the stronger the proportion of the acoustic signal in the measured sound pressure can be given the ambient volume and volume of the acoustic signal transmitter remain the same.

Further features and advantages of the invention result from the following description of exemplary embodiments with reference to the attached figures. Show it:

Fig. 1 is a block diagram of a telecommunications device according to the invention;

2 shows a first example of an operating method of such a telecommunication device; and

3 shows a second example of an operating method.

1 shows in the form of a highly schematic or idealized block diagram the structure of a telecommunication device according to the invention.

A transmitter-receiver unit 2 is connected to an antenna 1 and is connected to a base station of a mobile radio network.

Communication system received radio signal converts into a sequence of digital symbols and symbols, the user data, ie Forwarding data intended for a user of the device, such as voice or short messages, to a signal processor 3 and forwarding symbols, which contain signaling information, to a control unit 4. The symbols forwarded to the control unit 4 include, in particular, those which indicate the arrival of a call intended for the terminal.

An oscillator 5 as a tactile signal transmitter and a buzzer 6 or loudspeaker as an acoustic signal transmitter are connected to the control unit.

A loudspeaker 7 and a microphone 8, which are connected to the signal processor 3, serve to output a received speech signal to a user or to record the user's speech. The microphone 8 is connected to an input of the control unit 4 via a narrow-band frequency filter 9 and a measuring circuit 10.

All of the components mentioned are accommodated in a housing, not shown in the figure, in which the microphone 8 and the buzzer 6 are also separated from one another by a structure-borne noise-damping material, such as a foam filling or the like. In the simplest case, the components for structure-borne sound absorption accommodated in the housing can also suffice if the microphone 8 and the buzzer 6 are accommodated at a sufficient distance from one another, preferably at opposite ends of the housing.

The control unit 4 has a plurality of operating modes with regard to the response to incoming calls which can be set by a user. A first, conventional mode is the readiness of the buzzer 6, ie an acoustic signal sounds in the event of a call. Another conventional mode is the readiness of the vibrator 5, ie in the event of a call, it begins to move. The Operation in the third operating mode is explained in more detail below with reference to FIGS. 2 and 3.

Fig. 2 shows a first example of the operation of the control unit 4 in the event of an incoming call. It first checks (step S1) which is the operating mode set by a user. If the generation of an acoustic or a tactile call signal has been preselected by the user, the control unit 4 immediately actuates the corresponding signal transmitter (steps S2 or S3).

In the third operating mode, the control unit 4 first begins to operate the buzzer 6 to generate an acoustic call signal (S4). The acoustic call signal reaches the microphone 8, a portion of the electrical output signal of the microphone 8, expediently that which corresponds to the most intensive frequency of the buzzer 6, passes through the filter 9, and the amplitude of the filter output signal is measured by the measuring circuit 10. The analog or digitized measured value is read by the control unit 4 (S5).

The control unit 4 compares the measured value with a limit value specified by the manufacturer of the telecommunication device or set by the user (S6). If the measured volume exceeds the limit value, this is an indication that the sound propagation from the buzzer 6 to the microphone 8 is essentially unimpeded by the air surrounding the device, so that the device is most likely not being carried in a pocket on the user's body , but may be free and open. In this case, the generation of the acoustic call signal continues.

If the limit is undershot, this is an indication of sound absorption between the buzzer 6 and the microphone 8 or that the device may be worn on the body of the user. In such a case it is necessary to operate the vibrator so that the user notices the incoming call (S3).

If it is determined that the limit value is not reached, the buzzer 6 can be switched off when going to step S3. However, this is not absolutely necessary. Rather, the possibility can be provided for the user to preset whether the buzzer should be switched off in this case or not. For example, a user who is frequently in places where an acoustic signal is annoying will opt for the buzzer to switch off automatically, a user who travels outdoors a lot and who has the possibility that the device is in a coat pocket worn where the swinging motion is not necessarily noticeable, will rather choose to keep the acoustic call signal.

The volume measurement in S5 does not need to take more than a tenth of a second. Thus, it is possible to limit the acoustic call signal to a short beep of no more than a tenth of a second in an environment in which it is disruptive, which, in contrast to repeated ringing, will hardly be perceived by uninvolved persons.

Fig. 3 shows a further development of the working method of the control unit 4, which is particularly designed to avoid any disturbance of uninvolved people by an acoustic call signal. The steps S1, S2, S3 of this method correspond to those in FIG. 2 and are not described again.

When the telecommunication device is in the third operating mode, it starts at first in order to generate an audible ringing signal with a level that is significantly below that which is set by the user as the normal signal level (step _S4.. In step S5, as already described above, the volume with which this call signal reaches the microphone 8 is measured. When comparing the measured volume with the limit value in step S6 ^V , this limit value is of course proportional to the input power of the buzzer 6. Exceeding the limit value, ie undamped sound propagation between buzzer and microphone, can be detected even at very low volume of the call signal. In this case, the acoustic call signal is generated with the normal volume preset by the user (S2). If, for example, due to strong ambient noise, it is still not possible to assess whether the limit value has been exceeded, the volume is increased (S7) and the assessment of step S6 is repeated. If this assessment finally shows that the limit is undershot, the acoustic call signal is switched off (S8) and only the tactile call signal is generated (S3).

Since, in the case of a device worn on the body, strong ambient noises are not to be expected, a volume which is well below the normal volume of the acoustic call signal and which is damped by the user's clothing is generally sufficient for the assessment of step S6 other people are no longer noticeable.

A large number of modifications of the principle of the invention are still possible. So the acoustic signal, on the basis of which the exceeding of the limit value is assessed, does not necessarily have to be a call signal that an incoming one

Indicates call. Rather, this signal could be generated periodically, regardless of the arrival of a call, so that when a call arrives, the control unit 4 "knows" in advance whether it has to operate the buzzer 6 or the vibrator 5. In order to enable an even more reliable assessment of whether the telecommunication device is in a pocket or lying open, it can also be provided that the buzzer 6 generates a call signal with at least two different frequencies, simultaneously or in succession, and that the filter 9 and measuring circuit 10 are designed to selectively filter and measure both frequencies. In this variant, the fact that high frequencies are more easily attenuated than low frequencies can be used to assess the environment in which the telecommunication device is located on the basis of the intensity ratio of the two received frequencies.

Claims

claims

1. Telecommunication device with an acoustic and a tactile signal transmitter (6, 5), wherein at least the tactile signal transmitter (5) can be operated optionally for signaling an incoming call, and a microphone (8), characterized by a device for measuring an am Microphone (8) applied sound pressure and for actuating the tactile signal generator (5) depending on the measured sound pressure.

2. Telecommunication device according to claim 1, characterized in that the device performs the measurement of the sound pressure while the acoustic signal transmitter (6) is running.

3. Telecommunication device according to claim 2, characterized in that the device comprises a filter (9) matched to the sound spectrum of the acoustic signal transmitter (6).

4. Telecommunication device according to claim 2 or 3, characterized in that it actuates the tactile signal transmitter (5) in the event of a call if a sound pressure has been measured below a limit value.

5. Telecommunication device according to claim 2, 3 or 4, characterized in that it does not actuate the tactile signal transmitter (5) in the event of a call if a sound pressure has been measured above a limit value.

6. Telecommunication device according to claim 4 or 5, characterized in that the limit value (or the limit values) can be set by a user.

7. Telecommunication device according to claim 2 or 3, characterized in that the device for measuring the sound pressure at at least two frequencies and for actuating the tactile signal transmitter (5) is designed as a function of the ratio of the sound pressure measured at the frequencies.

8. Telecommunication device according to one of claims 2 to 7, characterized in that the device carries out the measurement when the acoustic signal generator (6) begins to generate a call signal.

9. Telecommunication device according to claim 8, characterized in that the acoustic signal generator (6) is able to generate a call signal with increasing volume when a call arrives.

10. Telecommunication device according to one of claims 2 to 9, characterized in that structure-borne noise damping means between the acoustic signal transmitter (6) and

Microphone (8) are provided.

11. Method for operating a telecommunication device with an acoustic (6) and a tactile (5) signal transmitter, with the steps

Measuring a sound pressure on the telecommunication device,

Actuation of the tactile signal generator (5) to generate a call signal depending on the measured sound pressure.

12. The method according to claim 11, characterized in that the measurement of the sound pressure is carried out while the acoustic signal generator (6) generates a signal.

13. The method according to claim 11, characterized in that the measurement of the sound pressure is carried out when the Acoustic signal generator (6) begins to generate a call signal.