|Publication number||USRE42093 E1|
|Application number||US 12/153,624|
|Publication date||Feb 1, 2011|
|Filing date||Mar 19, 2003|
|Priority date||Mar 20, 2002|
|Also published as||EP1488662A1, EP1488662B1, EP1931171A2, EP1931171A3, EP1931171B1, US7231037, US20050105718, WO2003079722A1|
|Publication number||12153624, 153624, PCT/2003/188, PCT/DK/2003/000188, PCT/DK/2003/00188, PCT/DK/3/000188, PCT/DK/3/00188, PCT/DK2003/000188, PCT/DK2003/00188, PCT/DK2003000188, PCT/DK200300188, PCT/DK3/000188, PCT/DK3/00188, PCT/DK3000188, PCT/DK300188, US RE42093 E1, US RE42093E1, US-E1-RE42093, USRE42093 E1, USRE42093E1|
|Inventors||Niels C. S. Hansen, Ole N. Christensen|
|Original Assignee||Sennheiser Communications A/S|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (32), Referenced by (1), Classifications (23), Legal Events (1)|
|External Links: USPTO, USPTO Assignment, Espacenet|
The invention relates to telecommunication systems and headsets, especially but not only headsets for telecommunication purposes. Such telecommunication system and headset comprises a microphone for receiving a near signal to be transferred away from a user and an output transducer for outputting a remote signal transferred to the user.
In the following reference is only made to a headset. It should be appreciated that the system also relates to similar functioning parts of telecommunication systems, such as handsets and connected devices. It is well known that shocks occasionally occur in telecommunication systems. These shocks are impulses of a significant voltage, which when they are transferred to the telephone and the headset are ejected as equivalently high sound levels to the headset user's ear or ears. The sound pressure level may be as high as 130 to 140 dB. It is fair to say that the headset itself does not cause the shock but only transmits this to the wearer of the headset. It is evident that when subjected to such signal, the user may suffer hearing damage and in addition to this may experience a shock condition.
When using a normal handset of a telephone, the user may, due to the fact that this is held by hand, quickly remove this from the ear and thereby avoid significant damage from the shock. When a headset is used in connection with a telecommunication system, the output transducer will normally be placed in a fixed position in relation to an ear and maintained in position by means of a hook over the ear or a headband. The removal is hereby not effected as quickly as in connection with the handset, which leads to an increased risk of damage of the hearing. A headset is however necessary for many receptionists and call centre employees due to the nature of their job, and due to the fact that these groups are using the telephone for a significant number of hours every day, making the use of a handset impossible, or at least less practical.
Due to this situation a number of attempts have been made to cope with the problem of the shock. The most common attempt comprises placing in parallel with the output transducer a number of diodes having the function of cutting the signal to a certain extent when a shock arises. This is however not very effective and there is still a significant risk that the occurrence of a shock may lead to damage of the hearing ability of a headset user.
For this reason there is a need for improving the headset and/or the telephone system in a manner that improves the ability of the headset to resist the transmission of the shock arising in the telephone system to the headset user.
The main objective of the present invention is therefore to improve a telephone system in a manner that improves the ability of the system to resist the transmission of the shock arising in the telephone system to the headset user.
According to the invention this objective is achieved by means of a system wherein a compressor system is used in conjunction with the input line to reduce the output signal level.
By making the construction in this manner the output signal will immediately be reduced when the input signal reaches a certain level. Thereby, the immediate risk of damaging the hearing of the telephone system user is significantly reduced by a system that can provide its function independent of additional power supply, i.e., the system relies entirely on the power supplied by the telephone line.
The compressor circuit may in a preferred embodiment be adapted to be operable on the audio signal alone, without additional power supply.
In a preferred embodiment the compressor system may comprise an electronically adjustable shunt resistance mounted in parallel with the speaker, and being realised by a MOS-FET transistor, a fall resistance in series with the speaker and the shunt resistance as well as a rectifier and peak detection/doubler circuit in the form of two schottky diodes and two capacitors. The system further comprises a DC separating capacitor, two capacitors for controlling the attack and release times for the attenuation as well as a protecting Zener diode.
The increase in the output signal at increasing input levels above an accepted maximum (in a circuit without PTC resistance) is not dependent of the time during which the input signal has been applied, but depends on the fact that the MOS-FET transistor has reached its minimum resistance value and that an increased input signal hereafter will not give rise to any attenuation of the signal. In this situation a change of the resistance to a PTC resistance will smoothen the output, as the PTC resistance will be heated due to the effect applied to it and hence give rise to a significant increase in resistance
When the shock signal climbs to a certain level the transistor will not be able to clamp the signal further and therefore raise will be seen on the output.
By including a variable resistance in the input line, remedy may be provided for this situation and the output level will even be reduced more than before.
Preferably the resistance is automatically variable in response to the load.
In a preferred embodiment the resistance is a so-called PTC resistance (Positive Temperature Coefficient).
The system as explained in the foregoing may advantageously be built into a headset, hereby enabling the application of an effective output reduction system in connection with telephone systems without this feature.
The invention will be explained more detailed in the following description of a preferred embodiment with reference to the drawings.
The circuitry shown in
The audio signal from the telephone is transmitted to the two input terminals R+ and R− and via a small fall resistance to the speaker. The detector circuit simultaneous detects the input signal and this signal is rectified and the peak level is transferred. This detector voltage is transmitted to the gate terminal on the MOS-FET transistor Q1. At normal listening level the detector voltage will not be sufficiently high to activate the MOS-FET transistor Q1, and hence, the circuit will be inactive and the output voltage to the speaker will alone be the voltage relationship between the small fall resistance R1 and the somewhat larger resistance in the speaker. This leads to an insignificant attenuation below IdB. If the audio signal is increased to above the limit for harmful sound pressures, the detector voltage reach a level controlling the MOS-FET transistor Q1 increasingly and have the effect that the resistance of this will drop with the result that the output voltage to the speaker decrease and the sound pressure will be reduced.
At very high level audio signals the power that is left in the circuit can reach very high levels when the resistance R1 is a conventional resistance. Due to this a PTC (Positive Temperature Coefficient) resistance is inserted as resistance R1. At very high audio signals the large effect in the R1 will have the effect that the resistance value in R1 increases and the effect in the circuit will decrease. At the same time the signal to the speaker is further reduced.
In a preferred embodiment as shown in
The curves show the sound pressure produced by a headset as a function of the sound pressure applied.
The first curve marked: “Without protection”, for a headset without built-in protection shows that the sound pressure output equals the sound pressure input.
The second curve marked “Diode protection”, for a headset with built-in protection in the form of a fall resistance and back-to-back diodes in parallel with the speaker, shows that the increase in the sound pressure output is reduced at sound pressures above 110 dB and reaches a level at 118 dB at a sound pressure input at 134 dB.
The third curve marked “Protection according to invention”, for a headset with a preferred embodiment of the present invention. The curve shows the unique “foldback sound limiting” characteristic, where the sound pressure output follows the sound pressure input until the circuitry reaches a predetermined detector voltage level at 102 dB. At this level the sound pressure output is attenuated to a comfortable level of 90 dB when the sound pressure input exceeds detector voltage and the sound pressure level of 90 dB is maintained even if the applied sound pressure is increased above approx. 134 dB. As soon as the sound pressure input falls below the detector voltage level of 102 dB the circuit is deactivated and the sound pressure output follows the sound pressure input.
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|U.S. Classification||379/412, 330/10, 381/94.8, 381/73.1, 381/74, 381/10, 379/88.28, 363/21.05, 381/72, 381/75|
|International Classification||H04M1/20, H04B1/64, H04M1/60, H04R5/033, H04R3/00|
|Cooperative Classification||H04M1/6016, H04R5/033, H04B1/64, H04R3/00|
|European Classification||H04R5/033, H04M1/60R, H04B1/64, H04R3/00|