KR20060082543A - Low-power wireless transceiver - Google Patents

Abstract

It is an object of the present invention to provide a low power wireless transceiver.

The low power radio transceiver of the present invention includes a first radio transceiver 100 and a second radio transceiver 200, wherein the first radio transceiver 100 is based on a wake-up selection (WS). A wake-up signal generator 110 for generating a wake-up signal corresponding to the set ID; And a first infrared transmitter 130 for converting the wakeup signal of the wakeup signal generator 110 into an infrared wakeup signal, and the second wireless transceiver 200 receives the received infrared wakeup signal. A second infrared ray receiver 210 for converting into an electrical wake-up signal; After recovering the wakeup signal from the second infrared receiver 210 to an ID, it is determined whether the restored ID matches a preset unique ID, and if it matches, supplying a wakeup voltage to the second radio transceiver. The wakeup signal processor 220 is provided.

Low Power, Wireless Transmitter, Wireless Receiver, Wake-Up, Control Signals, Data

Description

LOW-POWER WIRELESS TRANSCEIVER}

1 is a block diagram of a conventional low power wireless transceiver.

2 is a block diagram of a low power wireless transceiver according to the present invention.

Explanation of symbols on the main parts of the drawings

100: first wireless transceiver 110: wake-up signal generation unit

120: control signal processor 130: first infrared transmitter

140: first infrared receiver 150: data transmitter

200: second wireless transceiver 210: second infrared receiver

220: wake-up signal processing unit 230: control signal generation unit

240: second infrared transmitter 250: data receiver

SW: wake-up switch

The present invention relates to a low-power wireless transceiver, and more particularly, by transmitting a control signal and a wake-up signal such as a normal acknowledgment (ACK), an abnormal acknowledgment (NACK) in the infrared, and transmitting the data in RF, the overall current consumption The present invention relates to a low power wireless transceiver capable of reducing power consumption and operating at low power and further simplifying a circuit.

In general, as the utility of wireless communication increases, various types of connection networks in which wires and wireless are integrated are being established. Accordingly, requirements for low speed, low cost, and low power technical specifications are being raised in the wireless communication field. . In addition, recently, a number of standards have been published that can be widely used in various applications requiring a low data rate over the air, and thus a method for realizing ultra-low power is required.

In general, a communication system needs to always receive all signals from a transmitter in order to receive data from a transmitter. However, in order to reduce current consumption, a receiver is operated at regular intervals to determine whether a signal is present.

However, in an actual receiver, a circuit unit such as an oscillator and a receiver is driven to demodulate meaningless signals that do not need to be received or need to be received, and many have to supply power to a modem to perform demodulation. It is consuming power.

In order to secure the disadvantage of the power consumption has been proposed a wireless transceiver as shown in FIG.

1 is a block diagram of a conventional low power wireless transceiver.

The conventional low power radio transceiver shown in FIG. 1 includes a radio transmitter 10 and a radio receiver 20. The radio transmitter 10 transmits a wake-up signal using a low frequency LF. And an antenna ANT12 for transmitting data, and a control signal such as normal acknowledgment (ACK) and abnormal acknowledgment (NACK). The control signal receiving unit 13 and the antenna ANT13 for.

The wireless receiver 20 includes an antenna ANT21 and a LF receiver 21 for receiving a wake-up signal of low frequency LF, and includes an antenna ANT22 and a data receiver 22 for receiving data. Also, an antenna ANT23 and a control signal transmitter 23 for transmitting control signals such as normal acknowledgment (ACK) and abnormal acknowledgment (NACK) are included.

In such a conventional wireless transceiver, the baseband unit should always operate regardless of whether the wakeup signal is received to check whether the wakeup signal is its own wakeup signal, that is, to confirm the ID included in the signal. Or wake up periodically.

However, in the conventional radio transceiver, such a low frequency (LOW Frequency), using a separate control signal transmission and receiver in addition to the data transmission and receiver, power consumption is large, there is a limit to reduce the power consumption.

The present invention has been proposed to solve the above problems, and its object is to transmit control signals and wake-up signals such as normal acknowledgment (ACK) and abnormal acknowledgment (NACK) to infrared rays, and to transmit data to RF. By implementing the present invention, it is possible to reduce the total current consumption, to operate at low power, and to provide a low power wireless transceiver that can be further miniaturized by simplifying a circuit.

In order to achieve the above object of the present invention, the low power wireless transceiver of the present invention,

A low power radio transceiver comprising a first radio transceiver and a second radio transceiver,

The first wireless transceiver

A wakeup signal generator configured to generate a wakeup signal corresponding to a predetermined ID according to the wakeup selection; And

A first infrared ray transmitter for converting the wakeup signal of the wakeup signal generator into an infrared wakeup signal,

The second wireless transceiver

A second infrared receiver for converting the received infrared wakeup signal into an electrical wakeup signal; And

After recovering the wake-up signal from the second infrared receiver to an ID, it is determined whether the restored ID coincides with a preset unique ID, and if so, a wake-up signal for supplying a wake-up voltage to the second radio transceiver. Processing

Characterized in having a.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a low power wireless transceiver according to the present invention.

Referring to FIG. 2, a low power wireless transceiver according to the present invention includes a first wireless transceiver 100 and a second wireless transceiver 200.

The first wireless transceiver 100 includes a wakeup signal generator 110 for generating a wakeup signal corresponding to a predetermined ID according to a wakeup selection (WS), and a control signal processor for receiving and receiving an input control signal. 120 and the first infrared transmitter 130 for converting the wakeup signal of the wakeup signal generator 110 into an infrared wakeup signal, and converting the received infrared control signal into an electrical control signal to control the control. A first infrared receiver 140 for transmitting to the signal processing unit 120, and a data transmitter 150 for transmitting the data to be transmitted as an RF signal.

The second wireless transceiver 200 restores a second infrared receiver 210 for converting the received infrared wakeup signal into an electrical wakeup signal and a wakeup signal from the second infrared receiver 210 with an ID. After that, it is determined whether the restored ID matches the preset unique ID, and if it is matched, a wake-up signal processing unit 220 for supplying a wake-up voltage to the second radio transceiver, and a normal acknowledgment (ACK) upon request. Or the wake-up switching voltage from the wake-up signal processing unit 220 to generate a control signal such as an abnormal acknowledgment (NACK) and the like. A wake-up switching unit (SW) for supplying the second wireless transceiver (200), a second infrared ray transmitting unit (240) for converting a control signal generated by the control signal generator (230) into an infrared control signal, RF signal And a data receiving unit 250 for receiving data coming listed.

When the control signal received by the control signal processor 120 is an abnormal acknowledgment (NACK) signal, the data transmitter 150 transmits a data baseband unit 151 for retransmitting data, and the transmission data. A modulator 152 for modulating the signal from the baseband unit 151, a power amplifier 153 for amplifying the power of the signal from the modulator 152, and a signal from the power amplifier 153. A band pass filter 154 for passing the signal through a predetermined band, and a transmission antenna ANT1 for transmitting a signal from the band pass filter 154.

The data receiver 250 includes a reception antenna ANT2 for receiving a signal from the transmission antenna ANT1, a bandpass filter 251 for passing the signal from the reception antenna ANT2 into a predetermined band, A low noise amplifier 252 for amplifying the signal from the bandpass filter 251 with low noise, a demodulator 253 for demodulating the signal from the low noise amplifier 253 and restoring it to original data; Check the error on the received data from the grandfather 253 to confirm normal reception or abnormal reception, and the control signal generator 230 receives a control signal such as normal acknowledgment (ACK) or abnormal acknowledgment (NACK). A reception database baseband unit 254 requesting generation is included.

The switching unit SW is turned on by the wake-up switching voltage from the wake-up signal processing unit 220 to supply the wake-up voltage from the power supply unit to the data receiving unit 250, and And a second switch SW2 that is turned on by the wakeup switching voltage from the wakeup signal processor 220 and supplies the wakeup voltage from the power supply to the control signal generator 230.

Hereinafter, the operation and effects of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 2, when the first wireless transceiver 100 of the low power wireless transceiver according to the present invention transmits a wake-up signal to infrared rays, the second wireless transceiver 200 receives the wake-up signal to infrared rays and wakes up. Up, wireless data communication using RF is performed between the first wireless transceiver 100 and the second wireless transceiver 200. In the wireless data communication process, the second wireless transceiver 200 is a normal data. An acknowledgment (ACK) and an abnormal acknowledgment (NACK) are performed to transmit a control signal corresponding thereto to the first wireless transceiver 100 in infrared. Here, when the control signal corresponds to an abnormal acknowledgment (NACK), the first radio transceiver 100 performs data retransmission.

First, the wakeup process using infrared rays will be described.

The wakeup signal generator 110 of the first wireless transceiver 100 generates a wakeup signal corresponding to a predetermined ID according to a wakeup selection (WS) by the user, and transmits the wakeup signal to the first infrared transmitter 130. The first infrared transmitter 130 converts the wakeup signal of the wakeup signal generator 110 into an infrared wakeup signal and transmits the wakeup signal to the second wireless transceiver 200.

Subsequently, the second infrared receiver 210 of the second wireless transceiver 200 converts the received infrared wakeup signal into an electrical wakeup signal and transmits the wakeup signal processor 220 to the wakeup signal processor 220. After reconstructing the wakeup signal from the second infrared receiver 210 to the ID, the 220 determines whether the restored ID matches a predetermined unique ID, and if so, wakes up the wakeup switching voltage. Supply to the part (SW).

In this case, the wakeup switching unit SW is turned on by the wakeup switching voltage from the wakeup signal processing unit 220 to supply the wakeup voltage from the power supply unit to the second wireless transceiver 200. Accordingly, the second radio transceiver 200 is woken up.

Referring to the switching unit SW, the switching unit SW may include a first switch SW1 and a second switch SW2, wherein the first switch SW1 is the wakeup signal processor. It is turned on by the wakeup switching voltage from 220 to supply the wakeup voltage from the power supply to the data receiver 250. In addition, the second switch SW2 is turned on by the wakeup switching voltage from the wakeup signal processor 220 to supply the wakeup voltage from the power supply to the control signal generator 230.

According to the wake-up operation as described above, the first radio transceiver 100 transmits wake-up data corresponding to the intended transceiver as an infrared signal. Then, the signal received through the second infrared receiver 210, which is an infrared sensor of the second wireless transceiver 200, is received by the wakeup signal processor 220 in charge of baseband processing and compared with a unique ID. If so, the switch is turned on to operate the circuit of the second radio transceiver 200. In synchronization with this switching operation, each block of a receiver such as a low noise amplifier (LNA) and a mixer (Mixer) including an oscillator is activated and the second radio transceiver 200 consumes a current.

Next, a wireless data communication process using RF will be described.

When the control signal received by the control signal processor 120 is an abnormal acknowledgment (NACK) signal while the transmission data baseband unit 151 of the data transmitter 150 performs a normal data transmission process, After the retransmission is performed, the modulator 152 modulates the signal from the transmission database baseband unit 151, and the modulated signal is amplified by the power amplifier 153 and then a bandpass filter ( In 154, the signal is passed through a predetermined band and transmitted through the transmission antenna ANT1.

Subsequently, the receiving antenna ANT2 of the data receiving unit 250 receives a signal from the transmitting antenna ANT1, and the received signal is passed through a band pass filter 251 into a predetermined band and then amplified with low noise. After amplifying with low noise in the unit 252, the demodulator 253 recovers the original data. This recovered data is provided to the receiving data baseband portion 254.

The reception database band unit 254 checks an error on the reception data from the demodulation unit 253 to confirm normal reception or abnormal reception, thereby confirming a normal acknowledgment (ACK) to the control signal generator 230. Request generation of a control signal such as an abnormal acknowledgment (NACK).

Next, a process of transmitting control signals using infrared rays will be described.

First, the control signal generator 230 generates a control signal such as normal acknowledgment (ACK) or abnormal acknowledgment (NACK) according to a request of the reception database baseband unit 254, and the control signal is a second signal. The infrared transmitter 240 is converted into an infrared control signal and transmitted to the first wireless transceiver 100.

At this time, the first infrared receiver 140 of the first wireless transceiver 100 converts the received infrared control signal into an electrical control signal and transmits it to the control signal processor 120, and the control signal processor 120 is The received control signal is received and processed, and the received control signal such as a normal acknowledgment (ACK) or an abnormal acknowledgment (NACK) signal is transmitted to the transmission database band unit 151.

If the control signal is an abnormal acknowledgment (NACK) signal, the transmission data baseband unit 151 requests data retransmission.

According to the control signal transmission operation as described above, the control signal between the first wireless transceiver 100 and the second wireless transceiver 200 is composed of a very small bit compared to the data signal, the normal acknowledgment (ACK) ) Or an acknowledgment signal such as an abnormal acknowledgment (NACK) signal. In order to transmit a control signal consisting of fewer bits in the second wireless transceiver 200, the second wireless transceiver 200 must include a separate transmitter, and the first wireless transceiver 100 also includes a separate receiver. It should be provided.

At this time, if infrared rays are used to transmit and receive a small bit of control signals, the structures of the first and second radio transceivers can be greatly simplified.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, but is defined by the claims, and the apparatus of the present invention may be substituted, modified, and modified in various ways without departing from the spirit of the present invention. It is apparent to those skilled in the art that modifications are possible.

According to the present invention as described above, in the low-power wireless transceiver, by transmitting a control signal and wake-up signals such as normal acknowledgment (ACK), abnormal acknowledgment (NACK) in the infrared, by transmitting the data in RF, The overall current consumption can be reduced, so it can be operated at low power, and the circuit can be simplified, further miniaturizing.

Claims (6)

A low power radio transceiver comprising a first radio transceiver and a second radio transceiver, The first wireless transceiver A wakeup signal generator configured to generate a wakeup signal corresponding to a predetermined ID according to the wakeup selection; And A first infrared ray transmitter for converting the wakeup signal of the wakeup signal generator into an infrared wakeup signal, The second wireless transceiver A second infrared receiver for converting the received infrared wakeup signal into an electrical wakeup signal; And After recovering the wake-up signal from the second infrared receiver to an ID, it is determined whether the restored ID coincides with a preset unique ID, and if so, a wake-up signal for supplying a wake-up voltage to the second radio transceiver. Processing Low power wireless transceiver comprising a. The method of claim 1, wherein the first wireless transceiver A control signal processor configured to receive and process the received control signal; A first infrared receiver converting the received infrared control signal into an electrical control signal and transmitting the electrical signal to the control signal processor; And Data transmission unit for transmitting the data to be transmitted as an RF signal Low power wireless transceiver, characterized in that it further comprises. The method of claim 2, wherein the second wireless transceiver A control signal generator for generating a control signal such as normal acknowledgment or abnormal acknowledgment according to a request; A wakeup switching unit which is turned on by the wakeup switching voltage from the wakeup signal processing unit and supplies a wakeup voltage to the second radio transceiver; A second infrared ray transmitter for converting a control signal generated by the control signal generator into an infrared ray control signal; And Data receiving unit for receiving data carried in the RF signal Low power wireless transceiver, characterized in that it further comprises. The method of claim 2, wherein the data transmission unit A transmission database band unit for retransmitting data when the control signal received by the control signal processor is an abnormal acknowledgment signal; A modulator for modulating a signal from the transmission data baseband unit; A power amplifier for amplifying the power of the signal from the modulator; A band pass filter for passing the signal from the power amplifier to a predetermined band; And A transmit antenna for transmitting a signal from the bandpass filter Low power wireless transceiver comprising a. The method of claim 3, wherein the data receiving unit A receiving antenna for receiving a signal from the transmitting antenna; A band pass filter for passing the signal from the receiving antenna to a predetermined band; A low noise amplifier for amplifying the signal from the band pass filter with low noise; A demodulator for demodulating the signal from the low noise amplifier and restoring the original data; And A reception database band unit for checking a normal reception or abnormal reception by checking an error on the received data from the demodulator and requesting generation of a control signal such as normal acknowledgment or abnormal acknowledgment to the control signal generator; Low power wireless transceiver comprising a. The method of claim 3, wherein the switching unit A first switch turned on by the wakeup switching voltage from the wakeup signal processor to supply a wakeup voltage to the data receiver; And A second switch which is turned on by the wakeup switching voltage from the wakeup signal processor and supplies a wakeup voltage to the control signal generator; Low power wireless transceiver comprising a.

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