The disclosure relates to the field of communication, and in particular to a headset device, a headset, and a method for processing a signal by the headset device.
With the continuous development of mobile terminal technology, higher demands are proposed on the function and requirement of user's mobile terminal.
Taking a radio terminal receiving broadcast for example, existing mobile phone system has multiple clocks; the speed of the Central Processing Unit (CPU) is at least 100 MHz; the reference clock generally is between 12 MHz and 30 MHz; the frequency multiplication of the reference frequency is easy to reach between 72 MHz and 120 MHz. Each module of the mobile terminal has a different clock frequency; the mixed frequency generated between each frequency is extremely easy to fall in between 72 MHz and 120 MHz, enabling the internal signal of the entire mobile terminal to be strong in this frequency range. However, this frequency is just the receiving frequency range of Frequency Modulation (FM). Specifically, the receiving frequency range of FM is between 76.5 MHz and 108 MHz, thus the signal generated in this frequency range by the system of the mobile terminal is a noise relative to the FM signal.
Most mobile terminals having FM receiving function adopt a headset to serve as the antenna of the FM receiver, and noises of the mobile terminal are easy to couple to the antenna of the FM receiver. Therefore, impedance is increased in a headset circuit to prevent the noises from interfering with the antenna of the FM receiver.
As mobile terminal requires to be thinner and thinner and the screen requires to be bigger and bigger, the real device layout space becomes more and more intense and more and more layout and wiring problems are caused; especially in time division radio systems, Time Division Duplex (TDD) noise problem becomes more and more outstanding; if this problem is not resolved, users would hear interference caused by radio frequency in the headset; therefore, a circuit is added in the headset circuit to suppress the TDD noise.
In many existing designs, a magnetic bead or capacitor is connected to the headset audio signal in series or in parallel to alleviate the TDD noise, and a magnetic bead or capacitor is added in the headset circuit to reduce the noise interference on the FM signal. However, when a mobile terminal needs to reduce both the TDD noise interference and the FM interference, no solution has been proposed so far.
The disclosure is to provide a headset device, a headset, and a method for processing a signal by the headset device, to at least solve the above problem.
According to one aspect of the disclosure, a headset device is provided, which includes: a first interface, a second interface, a switch and an isolation unit, in which the isolation unit includes a first isolation body and a second isolation body connected to the first isolation body in parallel, and the first interface is connected to the second interface through the isolation unit, wherein the first interface is configured to connect to a ground network of the headset, wherein the ground network is a ground signal of the headset; the second interface is configured to connect to a ground line of a mobile terminal where the headset device is located; the first isolation body is configured to block a signal of a Frequency Modulation (FM) band from coupling to the ground network; the second isolation body is configured to block a signal of a cellular communication frequency band from coupling to the ground network; and the switch is configured to select to conduct the first isolation body, the first interface, and the second interface, or select to conduct the second isolation body, the first interface, and the second interface.
Preferably, the first isolation body and the second isolation body include a magnetic bead.
Preferably, the switch includes: a high-frequency analogue switch or a Complementary Metal Oxide Semiconductor (CMOS) switch.
Preferably, in the FM band an impedance of the first isolation body is greater than or equal to a first threshold, wherein the first threshold is used to ensure the capability of blocking the signal of the FM band from coupling to the ground network; and in the cellular communication frequency band an impedance of the second isolation body is greater than or equal to a second threshold, wherein the second threshold is used to ensure the capability of blocking the signal of the cellular communication frequency band from coupling to the ground network.
Preferably, the FM band is 100 MHz, and the first threshold is 600 ohm; and the cellular communication frequency band is 1 GHz or 2 GHz; and the second threshold is 600 ohm.
According to another aspect of the disclosure, a headset is provided, which includes the headset device described above.
According to a third aspect of the disclosure, a method for processing a signal by the headset device described above is provided, wherein the method is applied to a terminal and includes: receiving a function selection message, wherein the function selection message is used to indicate the selection of FM function or signal processing function of cellular communication frequency band; sending a control command, wherein the control command is used to set the switch to select the first isolation body to block a signal of the FM band from coupling to the ground network or to select the second isolation body to block a signal of the cellular communication frequency band from coupling to the ground network.
Preferably, setting the switch to select the first isolation body to block the signal of the FM band from coupling to the ground network includes: setting the switch to conduct the first isolation body, the first interface and the second interface; and setting the switch to select the second isolation body to block the signal of the cellular communication frequency band coupled to the ground network includes: setting the switch to conduct the second isolation body, the first interface and the second interface.
Preferably, in the FM band an impedance of the first isolation body is greater than or equal to a first threshold, wherein the first threshold is used to ensure the capability of blocking the signal of the FM band from coupling to the ground network; and in the cellular communication frequency band an impedance of the second isolation body is greater than or equal to a second threshold, wherein the second threshold is used to ensure the capability of blocking the signal of the cellular communication frequency band from coupling to the ground network.
Preferably, the FM band is 100 MHz; the first threshold is 600 ohm; the cellular communication frequency band is 1 GHz or 2 GHz; and the second threshold is 600 ohm.
In the disclosure, a first interface, a second interface, a switch and an isolation unit are adopted, in which the isolation unit includes a first isolation body and a second isolation body connected to the first isolation body in parallel, and the first interface is connected to the second interface through the isolation unit, wherein the first interface is configured to connect to a ground network of the headset; the second interface is configured to connect to a ground line of a mobile terminal where the headset device is located; the first isolation body is configured to block a signal of an FM band from coupling to the ground network; the second isolation body is configured to block a signal of a cellular communication frequency band from coupling to the ground network; and the switch is configured to select to conduct the first isolation body, the first interface, and the second interface, or select to conduct the second isolation body, the first interface, and the second interface; thus, the disclosure solves the problem that no solution has been proposed when FM interference needs to be reduced while TDD noise problem exists on one mobile terminal, and thus achieves the effect of reducing both FM interference and TDD noise on one mobile terminal and improves the practicability of the mobile terminal.
Drawings, provided for further understanding of the disclosure and forming a part of the specification, are used to explain the disclosure together with embodiments of the disclosure rather than to limit the disclosure, wherein:
The preferred embodiments are described in conjunction with the drawings as follows. It shall be understood that the embodiments of the present application and the features of the embodiments can be combined with each other if there is no conflict.
The embodiment provides a headset device.
The first interface 12 is configured to connect to a ground network of the headset, wherein the ground network is a ground signal of the headset; the second interface 14 is configured to connect to a ground line of a mobile terminal where the headset device is located; the first isolation body 182 is configured to block a signal of an FM range from coupling to the ground network; the second isolation body 184 is configured to block a signal of a cellular communication frequency range from coupling to the ground network; and the switch 16 is configured to select to conduct the first isolation body, the first interface, and the second interface, or select to conduct the second isolation body, the first interface, and the second interface.
With the above structure, by conducting the first isolation body, the first interface and the second interface using the switch, the first isolation body can block the signal of the FM range from coupling to the network, thus FM interference is avoided; or, by conducting the second isolation body, the first interface and the second interface using the switch, the second isolation body can block the signal of the cellular communication frequency range from coupling to the ground network, thus the interference from the cellular communication frequency range is reduced; therefore, the problem that no solution has been proposed when both FM interference and cellular communication frequency range interference need to be reduced is solved, that is, both FM interference and cellular communication frequency range interference can be reduced, and user experience is improved.
In a preferred embodiment, the first isolation body and the second isolation body include a magnetic bead. Through this preferred embodiment, signal can be isolated effectively.
During implementation, the switch adopts many modes, only if it can realize the selection function; preferably, a high-frequency analogue switch or a CMOS switch can be adopted. The two switches can reduce the signal interference generated during selection.
In another preferred implementation, in the FM range an impedance of the first isolation body is greater than or equal to a first threshold, wherein the first threshold is used to ensure the capability of blocking the signal of the FM range from coupling to the ground network; and in the cellular communication frequency range an impedance of the second isolation body is greater than or equal to a second threshold, wherein the second threshold is used to ensure the capability of blocking the signal of the cellular communication frequency range from coupling to the ground network. Through this preferred embodiment, the impedance ranges of the isolation bodies are determined, which is beneficial to accurately block the signal of the FM range coupled to the ground network and block the signal of the cellular communication frequency range coupled to the ground network. Preferably, the FM range is 100 MHz, the first threshold is 600 ohm, the cellular communication frequency range is 1 GHz or 2 GHz, and the second threshold is 600 ohm.
The embodiment provides a headset.
The embodiment provides a method for processing a signal by a headset device.
Step 302: a function selection message is received, wherein the function selection message is used to indicate the selection of FM function or signal processing function of cellular communication frequency range.
Step 304: a control command is sent, wherein the control command is used to set a switch to select the first isolation body to block a signal of the FM range from coupling to the ground network or to select the second isolation body to block a signal of the cellular communication frequency range from coupling to the ground network.
Through the above steps, the function selection message which is used to indicate the selection of FM function or signal processing function of cellular communication frequency range is received, and then the control command, which is used to set the switch to select the first isolation body to block a signal of the FM range from coupling to the ground network or to select the second isolation body to block a signal of the cellular communication frequency range from coupling to the ground network, is sent. Therefore, the problem that no solution has been proposed when both FM interference and cellular communication frequency range interference need to be reduced is solved, that is, both FM interference and cellular communication frequency range interference can be reduced, and user experience is improved.
In a preferred implementation, setting the switch to select the first isolation body to block a signal of the FM range from coupling to the ground network in Step 302 includes: setting the switch to conduct the first isolation body, the first interface and the second interface; setting the switch to select the second isolation body to block a signal of the cellular communication frequency range from coupling to the network ground includes: setting the switch to conduct the second isolation body, the first interface and the second interface. In this preferred implementation, the selection function of the switch is realized through the conduction of the first isolation body, the first interface and the second interface or the conduction of the second isolation body, the first interface and the second interface, thus the complexity of the system is reduced.
Preferably, in the FM range an impedance of the first isolation body is greater than or equal to a first threshold, wherein the first threshold is used to ensure the capability of blocking the signal of the FM range from coupling to the ground network; in the cellular communication frequency range an impedance of the second isolation body is greater than or equal to a second threshold, wherein the second threshold is used to ensure the capability of blocking the signal of the cellular communication frequency range from coupling to the ground network.
Preferably, the FM range is 100 MHz; the first threshold is 600 ohm; the cellular communication frequency range is 1 GHz or 2 GHz; and the second threshold is 600 ohm.
The disclosure is described below in conjunction with preferred embodiments. The following preferred embodiment combines the above embodiment and the preferred implementation.
This embodiment provides a method for receiving an FM signal and preventing a TDD noise by a headset, which includes Step 402 to Step 406 as follows.
Step 402: a device A having high impedance for frequency in the FM range is added in the ground network of the headset, to prevent the ground network of a terminal from coupling the noise caused by the frequency in the FM range to the ground network of the headset, wherein the ground network of the headset serves as a signal receiving network of a radio.
Step 404: a device B having high impedance for cellular communication frequency is added in the ground network of the headset, to prevent the ground network of the terminal from coupling the noise caused by the cellular communication frequency to the ground network of the headset.
Step 406: a switch between A, B devices and the ground network of the headset is added, and enabling the switch to have a selection function, that is, when the terminal selects the FM function, the circuit selects to pass through the device A; when the terminal is in the state of normal radio communication, the circuit selects to pass through the device B.
Through the above steps, the internal FM range signal of the mobile terminal is prevented from transmitting to the FM receiver, the reception strength of useful FM range signal is improved, and the TDD noise generated during the communication of the mobile terminal is prevented from coupling to the headset channel from the system.
This embodiment provides a headset circuit, which is implemented through Step 502 to Step 508 as follows.
Step 502: a high-frequency analogue switch or a CMOS switch is added in the ground network of the headset, and enabling the switch to have a one-out-of-two function, wherein the ground of the headset serves as the receiving antenna of a radio.
Step 504: a magnetic bead is connected to one of two paths of the switch in series, wherein the magnetic bead has high impedance in the cellular communication frequency, that is, the magnetic bead has an impedance of 600 ohm or higher in the cellular communication frequency such as 1 GHz or 2 GHz.
Step 506: a magnetic bead is connected to the other path of the switch in series, wherein the magnetic bead has high impedance in the FM frequency, that is, the magnetic bead has an impedance of 600 ohm or higher in the FM frequency which is 100 MHz.
Step 508: the magnetic beads connected to the two paths in series are connected to the ground network of the terminal system together.
The circuit implemented through the above steps can solve the problem of coexistence of TDD noise and radio signal, with simple structure and low cost.
This embodiment provides a headset circuit
Through the above embodiment, a headset device, a headset and a method for processing a signal by the headset device are provided; by conducting the first isolation body, the first interface and the second interface using the switch, the first isolation body can block the signal of the FM range coupled to the network, thus FM interference is avoided; or, by conducting the second isolation body, the first interface and the second interface using the switch, the second isolation body can block the signal of the cellular communication frequency range coupled to the ground network, thus the interference from the cellular communication frequency range is reduced. Through the above technical scheme, the internal FM range signal of the mobile terminal is prevented from transmitting to the FM receiving path, and in another application scene the internal radio communication system frequency noise of the terminal system is prevented from transmitting to the headset path; therefore, FM receiving signal-to-noise ratio is effectively improved and the headset would not receive interference during a call. It should be noted that not all implementations above can achieve these technical effects and some technical effects can be achieved by some preferred implementations only.
Obviously, those skilled in the art shall understand that the above-mentioned modules and steps of the disclosure can be realized by using general purpose calculating device, can be integrated in one calculating device or distributed on a network which consists of a plurality of calculating devices. Alternatively, the modules and the steps of the disclosure can be realized by using the executable program code of the calculating device. Consequently, they can be stored in the storing device and executed by the calculating device, or they are made into integrated circuit module respectively, or a plurality of modules or steps thereof are made into one integrated circuit module. In this way, the disclosure is not restricted to any particular hardware and software combination.
The descriptions above are only the preferable embodiment of the disclosure, which are not used to restrict the disclosure. For those skilled in the art, the disclosure may have various changes and variations. Any amendments, equivalent substitutions, improvements, etc. within the disclosure are all included in the scope of the protection of the disclosure.
Number | Date | Country | Kind |
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20110237552.0 | Aug 2011 | CN | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CN2012/071084 | 2/13/2012 | WO | 00 | 2/18/2014 |