US20180014266A1

Movatterモバイル変換

Info

Publication number: US20180014266A1
Application number: US15/432,885
Authority: US
Inventors: Peng-Sen CHEN
Original assignee: Pixart Imaging Inc
Current assignee: Airoha Technology Corp
Priority date: 2016-07-11
Filing date: 2017-02-14
Publication date: 2018-01-11
Anticipated expiration: 2037-02-14
Also published as: TW201803289A; US9877291B1

Abstract

A wireless transceiver apparatus includes a power detector, an analog signal receiving circuit at wireless signal reception side, and a processing circuit. The power detector is configured at wireless signal transmission side and used for detecting power of a power amplifier on a transmitting path of wireless signal transmission side. The analog signal receiving circuit is couple to the power detector and used for receiving a wireless signal form an antenna. Under signal reception mode, the analog signal receiving circuit transmits the received wireless signal to the processing circuit. Under interference detection mode, the analog signal receiving circuit transfers the received wireless signal (as interference) to the power detector, and the power detector is used for detecting the power of wireless signal to measure an interference power value and transmit the value to the processing circuit.

Description

BACKGROUND OF THE INVENTION1. Field of the Invention

The invention relates to a wireless transceiver scheme, and more particularly to a wireless transceiver apparatus and corresponding method.

2. Description of the Prior Art

Generally speaking, conventional wireless transceivers based on Bluetooth communication standard suffer from the interference of Wi-Fi signals especially when the signal power of Bluetooth communication is smaller than that of Wi-Fi signals. For amplifiers such as low-noise amplifier (LNA) at the wireless signal reception side of the conventional Bluetooth communication transceivers, the interference of Wi-Fi signals usually cause signal saturation for the amplifiers since the amplifiers are designed to be more sensitive and with higher gain values. Thus, even though partial Wi-Fi signal interference can be filtered out by using filter (s) at the post-stage circuit, however, the signal saturation inevitably causes the poor quality for signal reception. The interference of Wi-Fi signals will not always exist, continuously and always enabling the detection for the interference will inevitably need additional circuit element(s) for detection and also consume more power. Using additional circuit element(s) for detection often means that further circuit area is needed and configured to implement the additional circuit element (s). it is difficult to design an interference detection scheme for Bluetooth transceiver(s) with the advantage of power saving.

SUMMARY OF THE INVENTION

Therefore one of the objectives of the invention is to provide a wireless transceiver apparatus and method applied for the wireless transceiver apparatus, to solve the above-mentioned problems.

According to embodiment of the invention, a wireless transceiver apparatus is disclosed. The wireless transceiver apparatus comprises a power detector, an analog signal receiving circuit, and a processing circuit. The power detector is configured at a wireless signal transmission side and used for detecting power of a power amplifier on a transmitting path of the wireless signal transmission side. The analog signal receiving circuit is configured at a wireless signal reception side and coupled to the power detector, and is used for receiving a wireless signal form an antenna. The processing circuit is coupled to the analog signal receiving circuit. Under a signal reception mode, the analog signal receiving circuit transmits the received wireless signal to the processing circuit. Under an interference detection mode, the analog signal receiving circuit transfers the received wireless signal to the power detector, and the power detector detects a power of the received wireless signal to measure an interference power value and transmit the interference power value to the processing circuit.

According to the embodiments, a method used for a wireless transceiver apparatus is disclosed. The method comprises: providing a power detector configured at a wireless signal transmission side; providing an analog signal receiving circuit configured at a wireless signal reception side, the analog signal receiving circuit receiving a wireless signal form an antenna; under a signal reception mode, utilizing the analog signal receiving circuit to transmit the received wireless signal to a processing circuit; and, under an interference detection mode: transferring the received wireless signal from the analog signal receiving circuit to the power detector; and utilizing the power detector to detect a power of the received wireless signal to measure an interference power value and transmit the interference power value to the processing circuit.

These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is block diagram of a wireless transceiver apparatus according to an embodiment of the invention.

FIG. 2 is a diagram illustrating the signal processing flow of the wireless transceiver apparatus ofFIG. 1 when operating under the power calibration mode.

FIG. 3 is a diagram illustrating the signal processing flow of the wireless transceiver apparatus ofFIG. 1 when operating under the interference detection mode.

FIG. 4 is a diagram illustrating the signal processing flow of the wireless transceiver apparatus ofFIG. 1 when operating under the signal reception mode.

DETAILED DESCRIPTION

FIG. 1 is block diagram of awireless transceiver apparatus100 according to an embodiment of the invention. Thewireless transceiver apparatus100 comprises a wireless signal transmission side and a wireless signal reception side, and is used for transmitting a wireless signal and receiving a wireless signal, respectively. Thewireless transceiver apparatus100 can be applied to Bluetooth communication and includes a Bluetooth communication capability for receiving and sending a Bluetooth wireless communication signal (but not limited).

Bluetooth communication standard for example employs the frequency band of 2.4 GHz, and an adjacent frequency band for example is used by other communication standard such as Wi-Fi communication standard. The performance of a conventional wireless transceiver for Bluetooth communication is easily affected or influenced by Wi-Fi communication signals especially when the signal power of Bluetooth communication signal is smaller than the signal power of Wi-Fi communication signals. A low-noise amplifier (LNA) configured at the wireless signal reception side of the conventional transceiver for Bluetooth communication is usually designed with higher sensitivity for processing the signal and designed with a greater gain value. The LNA of the conventional transceiver usually and easily suffers from signal saturation resulted from the interference of Wi-Fi communication signals at adjacent frequency bands. A conventional scheme may employ a filter at a post-stage circuit to filter out partial interference generated from the Wi-Fi communication signals. However, the signal saturation for the LNA inevitably causes the poor quality for signal reception. Since the Wi-Fi communication signals may not always exist, continually and always detecting the interference of Wi-Fi signals would consume much power, and also needs an additional circuit for detection and thus more circuit areas are required to implement the additional circuit. It becomes more difficult to design a scheme for detection the interference source.

To solve the above-mentioned problems, thewireless transceiver apparatus100 of the embodiment is arranged to perform interference detection operation by using partial circuit(s) on a transmitting path at the wireless signal transmission side and/or is arranged to execute the interference detection operation at a specific timing designed based on Bluetooth communication standard. The partial circuit(s) is/are shared for signal transmission and interference detection. Thewireless transceiver apparatus100 can appropriately detect energy/power of the interference of other wireless signals in the air to avoid signal saturation introduced to an LNA of the front-end circuit and/or signal saturation for amplifier(s) of the post-stage circuit, with consideration of power saving and without occupying additional circuit areas (or without adding other circuit elements) at the same time.

Thewireless transceiver apparatus100 performs interference detection operation by using partial circuit element(s) on the transmitting path at the wireless signal transmission side. For example, thewireless transceiver apparatus100 employs at least a power detector, which is disposed on the transmitting path of the wireless signal transmission side and configured for performing power calibration upon a signal at the transmission side, to perform the interference detection operation. For signal transmission, the power detector is used for performing power calibration to maintain a wireless signal, to be transmitted to the air, at the same level. For interference detection, the power detector is used for detecting whether interference of other wireless signal exists and the power/energy of the interference. Since the power detector on the transmitting path at the transmission side is further employed to the perform interference detection operation, this would not need to implement more additional circuits to occupy additional circuit areas. Even additional detection circuits are not required.

Refer back toFIG. 1. In practice, thewireless transceiver apparatus100 includes atransmitting circuit101T on a signal transmitting path at the wireless signal transmission side, an analogsignal receiving circuit101R on a signal receiving path at the wireless signal reception side, anantenna unit102, and aprocessing circuit103. The transmittingcircuit101T includes a digital-to-analog converter (DAC)105, a low-pass filter (LPF)110, amixer115 connected to a local oscillation signal LO, apower amplifier120, atransducer125, and apower detector130. The analogsignal receiving circuit101R includes anamplifier140 such as a low noise amplifier (LNA), atransducer145, amixer150, a band-pass filter (BPF)155, and anamplifier160. The antenna unit1002 is used for sending and receiving wireless signals via Bluetooth communication standard. Theprocessing circuit103 includes amultiplexer165, an analog-to-digital converter (ADC)170, and asignal processing circuit175 wherein thesignal processing circuit175 can be a baseband control circuit or a digital signal processing circuit. In addition, thewireless transceiver apparatus100 further comprises four switch elements SW1-SW4. The switch element SW1 is selectively coupled between an output of thetransducer145 and an input of themixer150. The switch element SW2 is selectively coupled between the output of thetransducer145 and an input of thepower detector130. The switch element SW3 is selectively coupled between the output of thetransducer145 and another input of thepower detector130. The switch element SW4 is selectively coupled between the output of theamplifier160 and the input of themultiplexer165. The state (open or short) of each switch element SW1-SW4 can be controlled by thesignal processing circuit175 within theprocessing circuit103, and each switch element SW1-SW4 can be respectively turned on to become short or turned off to become open in response to different operations of thewireless transceiver apparatus100. The electrical connections between other circuit elements are illustrated onFIG. 1.

FIG. 2 is a diagram illustrating the signal processing flow of thewireless transceiver apparatus100 ofFIG. 1 operating under the power calibration mode. When thewireless transceiver apparatus100 enters the power calibration mode, thesignal processing circuit175 is arranged to control the switch elements SW1, SW2, and SW4 to become open and control the switch element SW3 to become short. Themultiplexer165 ofprocessing circuit103 is arranged to select the output signal of thepower detector130 as its output. As indicated by arrows shown inFIG. 2, the transmission signal ST passes through theDAC105,LPF110,mixer115,power amplifier120,transducer125,power detector130,multiplexer165, and theADC170, and is processed by these circuit elements correspondingly and finally transmitted to thesignal processing circuit175. Thepower detector130 is used for performing power detection upon the transmission signal ST to detect the signal power ofpower amplifier120 on the transmitting path at the wireless signal transmission side. Thesignal processing circuit175 can control thepower amplifier120 to perform the power calibration according to the detection result generated by thepower detector130, to maintain the power of the wireless transmission signal to be transmitted to the air at the same level substantially.

FIG. 3 is a diagram illustrating the signal processing flow of thewireless transceiver apparatus100 ofFIG. 1 operating under the interference detection mode. As shown inFIG. 3, when thewireless transceiver apparatus100 enters the interference detection mode, thesignal processing circuit175 is arranged to control the switch elements SW1, SW3, and SW4 to become open and control the switch element SW2 to become short. Themultiplexer165 ofprocessing circuit103 selects the output signal ofpower detector130 as its output. Under the interference detection mode, the wireless signal SR detected by thewireless transceiver apparatus100 is regarded as an interference signal rather than a data signal or a data packet. As indicated by arrows shown inFIG. 3, if the interference of Wi-Fi signals exists, then the signal interference will be received by theantenna unit102 and transmitted through theamplifier140,transducer145,power detector130,multiplexer165,ADC170, and finally transmitted to thesignal processing circuit175. That is, the analogsignal receiving circuit101R is arranged to transfer the received wireless signal (i.e. the Wi-Fi signal) to thepower detector130, and the received wireless signal (Wi-Fi signal) does not pass through themixer150,BPF155, and theamplifier160. Thepower detector130 performs power detection for the energy or power of Wi-Fi signal interference, to detect the power of Wi-Fi signal interference, measure an interference power value, and transmit the interference power value to theprocessing circuit103. TheADC170 ofprocessing circuit103 is arranged to convert the interference power value into a digital value, and thesignal processing circuit175 is arranged to adaptively control the gain value of at least one amplifier in the

amplifiers

140 and160 within the analogsignal receiving circuit101R according to the digital value under the signal reception mode, to avoid signal saturation.

FIG. 4 is a diagram illustrating the signal processing flow of thewireless transceiver apparatus100 ofFIG. 1 operating under the signal reception mode. Thesignal processing circuit175 is arranged to control the switch elements SW2 and SW3 to become open and control the switch elements SW1 and SW4 to become short. Themultiplexer165 ofprocessing circuit103 is arranged to select the output signal of theamplifier160 as its output. Under the signal reception mode, the wireless signal SR detected by thewireless transceiver apparatus100 is regarded as a dada signal or a data packet. As indicated by arrows shown inFIG. 4, the wireless signal SR transmitted with Bluetooth communication standard is received by theantenna unit102 and then is transmitted and received by the analogsignal receiving circuit101R. The wireless signal SR is sequentially transmitted through theamplifier140,transducer145,mixer150,BPF155,amplifier160,multiplexer165,ADC170, and finally transmitted to thesignal processing circuit175. When thewireless transceiver apparatus100 enters the analog reception mode to receive Bluetooth data packet(s), thesignal processing circuit175 can adaptively control the gain value of at least one amplifier in the

amplifiers

140 and160 within the analogsignal receiving circuit101R according to the interference detection result generated by thepower detector130, to avoid signal saturation. In practice, when the digital value is higher than a first threshold value, thesignal processing circuit175 can control the gain value of at least one amplifier as a first gain value. When the digital value is higher than a second threshold value, thesignal processing circuit175 can control the gain value of the at least one amplifier as a second gain value. By doing this, the interference of other signal sources can be reduced. The second threshold value is higher than the first threshold value, and the second gain value is smaller than the first gain value. The above-mentioned scheme for adjusting the gain value based on the threshold values is one embodiment for illustrative purposes. In other embodiments, a single threshold value can be used for deciding and adjusting the gain value(s) of the amplifier(s). For example, when the digital value is higher than the single threshold value, the gain value of an amplifier is decreased; instead, when the digital value is lower than the single threshold value, the gain value is increased.

It should be noted that the invention aims at utilizing at least the power detector, which is at the wireless signal transmission side and used for power calibration for the transmission signal, to perform interference detection operation. In other embodiments, the arrangement positions of switch elements SW1-SW3 can be adjusted and changed to further utilize thetransducer125 to perform interference detection operation. In practice, the arrangement position of switch element SW1 can be changed to be coupled between the output of theamplifier140 and the input of thetransducer145. The arrangement position of switch element SW2 can be changed to be coupled between the output of theamplifier140 and the input of thetransducer125. The arrangement position of switch element SW3 can be changed to be coupled between the output of thepower amplifier120 and the input of thetransducer125. The control of the corresponding switch elements is identical to that of switch elements as shown inFIG. 1, and is not detailed for brevity. Further, in another embodiment, the analogsignal receiving circuit101R can be configured to include theLNA140 and exclude theamplifier160. The operation of controlling the gain value (s) of amplifier (s) to avoid signal saturation resulted from other interference signals can comprise the operation of controlling the gain value of merely a single one amplifier within the analogsignal receiving circuit101R and/or the operation of controlling the gain values of two or more amplifiers. This also obeys the spirit of the invention.

Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.

Claims

What is claimed is:

1. A wireless transceiver apparatus, comprising:

a power detector, configured at a wireless signal transmission side and used for detecting power of a power amplifier on a transmitting path of the wireless signal transmission side;

an analog signal receiving circuit, configured at a wireless signal reception side and coupled to the power detector, the analog signal receiving circuit receiving a wireless signal form an antenna; and

a processing circuit, coupled to the analog signal receiving circuit;

wherein, under a signal reception mode, the analog signal receiving circuit transmits the received wireless signal to the processing circuit; under an interference detection mode, the analog signal receiving circuit transfers the received wireless signal to the power detector, and the power detector detects a power of the received wireless signal to measure an interference power value and transmit the interference power value to the processing circuit.

2. The wireless transceiver apparatus ofclaim 1, wherein the processing circuit is used for converting the interference power value to a digital value and controlling a gain value of at least one amplifier of the analog signal receiving circuit according to the digital value.

3. The wireless transceiver apparatus ofclaim 2, wherein when the digital value is greater than a first threshold value, the processing circuit is arranged to control and determine the gain value of the at least one amplifier as a first gain value; and, when the digital value is greater than a second threshold, the processing circuit is arranged to control and determine the gain value of the at least one amplifier as a second gain value to reduce interference wherein the second threshold value is higher than the first threshold value and the second gain value is smaller than the first gain value.

4. The wireless transceiver apparatus ofclaim 2, wherein the analog signal receiving circuit comprises:

a first amplifier, coupled to the antenna;

a mixer, coupled to the first amplifier;

a band-pass filter, coupled to the mixer;

a second amplifier, coupled to the band-pass filter;

wherein the processing circuit respectively controls a gain value of the first amplifier and a gain value of the second amplifier according to the digital value.

5. The wireless transceiver apparatus ofclaim 4, further comprising:

a first switch, disposed between the first amplifier and the mixer;

a second switch, disposed between the analog signal receiving circuit and the power detector;

a third switch, disposed between the power detector and the power amplifier on the transmitting path; and

a fourth switch, disposed between the analog signal receiving circuit and the processing circuit;

wherein under the signal reception mode, the processing circuit controls states of the first switch, the third switch, and the fourth switch become closed respectively; and under the power detection mode, the processing circuit controls the states of the first switch, the third switch, and the fourth switch become open respectively and controls a state of the second switch become closed.

6. The wireless transceiver apparatus ofclaim 1, wherein the wireless transceiver apparatus includes a Bluetooth communication capability, and under the signal reception mode the wireless transceiver apparatus is arranged to receive Bluetooth data packet(s) and is arranged to enable and enter the interference detection mode when is not arranged to receive the Bluetooth data packet(s).

7. The wireless transceiver apparatus ofclaim 6, wherein the wireless transceiver apparatus is arranged to enable and enter the interference detection mode before receiving a preamble signal of Bluetooth communication, or the wireless transceiver apparatus is arranged to enable and enter the interference detection mode after completely receiving one Bluetooth data packet.

8. A method used for a wireless transceiver apparatus, comprising:

providing a power detector configured at a wireless signal transmission side;

providing an analog signal receiving circuit configured at a wireless signal reception side, the analog signal receiving circuit receiving a wireless signal form an antenna;

under a signal reception mode, utilizing the analog signal receiving circuit to transmit the received wireless signal to a processing circuit; and

under an interference detection mode:

transferring the received wireless signal from the analog signal receiving circuit to the power detector; and

utilizing the power detector to detect a power of the received wireless signal to measure an interference power value and transmit the interference power value to the processing circuit.

9. The method ofclaim 8, further comprising:

converting the interference power value to a digital value; and

controlling a gain value of at least one amplifier of the analog signal receiving circuit according to the digital value.

10. The method ofclaim 9, wherein the step of controlling the gain value of the at least one amplifier of the analog signal receiving circuit according to the digital value comprises:

controlling and determining the gain value of the at least one amplifier as a first gain value when the digital value is greater than a first threshold value; and

controlling and determining the gain value of the at least one amplifier as a second gain value to reduce interference when the digital value is greater than a second threshold;

wherein the second threshold value is higher than the first threshold value and the second gain value is smaller than the first gain value.