KR102297144B1 - Electronic apparatus for controlling power of rf signal and operating method thereof - Google Patents

Abstract

The present disclosure relates to an electronic device capable of controlling the output of an RF signal and a method of operating the same.
An electronic device according to an embodiment of the present disclosure includes a proximity sensor configured to detect an external device approaching within a predetermined distance; an antenna configured to transmit and receive RF signals; RF modem for controlling to transmit and receive RF signals through the antenna; and a processor configured to control the RF modem, wherein the processor receives the detection signal through the proximity sensor, controls the RF modem to transmit the RF signal to an external device at a first strength, and receives the RF signal from the external device It is determined whether a response signal has been received, and as a result of the determination, when the response signal is not received, the RF modem may be controlled to transmit the RF signal to an external device at a second intensity greater than the first intensity.

Description

An electronic device capable of controlling the output of an RF signal and an operation method thereof

The present disclosure relates to an electronic device capable of controlling the output of an RF signal and a method of operating the same.

RF (Radio Frequency) or RF communication refers to wireless communication using high-frequency electromagnetic waves. RF communication is being used in a very wide field, from data communication, payment, security ID identification, to secondary uses using them.

Among them, RF communication used for short-distance communication is utilized in payment systems, etc. by taking advantage of high compatibility and fast communication speed. For example, Radio Frequency Identification (RFID), Near Field Communication (NFC), etc. may use RF communication.

NFC has recently been widely used due to the advantages of high security, compatibility, and fast recognition speed, and in particular, it is configured in smart mobile communication devices and used in various ways. Types of NFC include passive NFC, which communicates by modulating a received radiation wave without an independent power supply, and active NFC, which transmits a signal with independently supplied power.

However, in conventional RF communication, for example, NFC, etc., when transmitting a signal, the distance to the other terminal cannot be known, so it is common to maximize the power of the signal radiated from the antenna. Since it is difficult to know an appropriate signal output suitable for communication with the counterpart terminal, the signal is transmitted by maximizing the amount of power for transmitting the signal.

The prior art has a problem in that the recognition rate is lowered by transmitting the RF signal with the maximum output as described above. In particular, it is evident when the counterpart terminal also transmits an RF signal. For example, this problem is conspicuous in an active NFC device such as a smartphone. There may be several causes of this problem, and when transmitting at the maximum output, the counterpart terminal may not recognize it as a communication signal, but may recognize it as noise. In addition, since the counterpart terminal also transmits a signal with the maximum output, the signal of the counterpart terminal itself may be mixed with noise and the signal may not be recognized. Conversely, even if the counterpart terminal receives the RF signal and sends a response signal, the terminal Since an RF signal is being transmitted as an output, the signal recognition rate may decrease due to interference with its own signal. As a result, a response signal may not be received, and eventually there may be a problem that the terminals are not recognized with each other.

In addition, the prior art maximizes the output, that is, the output power, and there is a problem of heat generation of a circuit or device and excessive power consumption. Heat is related to the stability and lifespan of the device, and the problem of power consumption becomes a major issue, especially in the case of a portable terminal.

An object of the present disclosure is to provide an electronic device capable of improving the recognition rate of RF communication and minimizing power consumption by controlling the output of the RF signal, and an operating method thereof.

An electronic device according to an embodiment of the present disclosure includes a proximity sensor configured to detect an external device approaching within a predetermined distance; an antenna configured to transmit and receive RF signals; RF modem for controlling to transmit and receive RF signals through the antenna; and a processor configured to control the RF modem, wherein the processor receives the detection signal through the proximity sensor, controls the RF modem to transmit the RF signal to an external device at a first strength, and receives the RF signal from the external device It is determined whether a response signal has been received, and as a result of the determination, when the response signal is not received, the RF modem may be controlled to transmit the RF signal to an external device with a second strength greater than the first strength.

According to an embodiment of the present disclosure, a method for an electronic device to control an output of an RF signal includes: receiving a detection signal detecting an approach of an external device through a proximity sensor; transmitting an RF signal to an external device at a first strength; determining whether a response signal to the RF signal is received from an external device; When the response signal is not received as a result of the determination, the method may include transmitting the RF signal to an external device with a second intensity greater than the first intensity.

According to various embodiments of the present disclosure, the electronic device adjusts the output strength of the RF signal to transmit the RF signal with an appropriate output, thereby improving the recognition rate, and by transmitting only the maximum output, the problem of the prior art in which communication was not smooth can be solved

In addition, according to various embodiments of the present disclosure, since the electronic device consumes only an appropriate power for transmitting an RF signal, heat generation can be reduced and the power consumption can be reasonably reduced.

According to an embodiment of the present invention, the recognition rate can be further increased by correcting the frequency of the transmission signal so as to reduce the recognition disturbance due to noise by performing calibration of the RF signal.

1 is a diagram illustrating a state in which an electronic device controls an output of an RF signal according to an embodiment of the present invention.
2 is a block diagram illustrating the configuration of an electronic device according to an embodiment of the present invention.
3 is a flowchart illustrating a method for controlling an output of an RF signal by an electronic device according to an embodiment of the present invention.
4 is a flowchart illustrating a method of correcting a frequency of an RF signal by an electronic device according to an embodiment of the present invention.

In order to clearly explain the present invention, parts irrelevant to the description are omitted, and the same reference numerals are given to the same or similar elements throughout the specification.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement them. However, the present invention may be embodied in various different forms and is not limited to the embodiments described herein.

Hereinafter, 'RF signal' is a signal mainly transmitted by an electronic device, and may be a concept to be distinguished from a 'response signal' that an external device transmits or carries and receives by the electronic device, but the 'RF signal' It may refer to a general concept encompassing high-frequency signals, and in this case, it will be clearly understood by those of ordinary skill in the art. In addition, hereinafter, a signal is electromagnetic data and should be understood as a broad concept regardless of digital/analog and information contained therein.

1 is a diagram illustrating a state in which an electronic device controls an output of an RF signal according to an embodiment of the present invention. 1 , the electronic device 110 may transmit an RF signal and receive a response signal to communicate with the external device 120 . For example, the electronic device 110 may be a POS payment terminal, the external device 120 may be a smart mobile communication terminal capable of active RF communication, and the electronic device 110 may be a smart mobile communication terminal and an external device ( 120) may be a POS payment terminal. Also, the electronic device 110 and the external device 120 are not limited to examples and may include various electronic devices.

If the output strength of the RF signal transmitted by the electronic device 110 is too weak, the external device 120 may not receive or recognize the RF signal. As a result, smooth communication is difficult. Also, even if the output strength of the RF signal is too large, smooth communication may be difficult. This is because, as described above, it is recognized as noise or is affected by interference with a signal output by the external device 120 at the same maximum intensity. There is also a big problem of heat generation and power consumption.

The electronic device 110 according to an embodiment of the present invention may perform smooth communication by gradually increasing the output of the RF signal from the lowest intensity to find an appropriate output and transmitting the RF signal with the appropriate output. The electronic device 110 may increase the communication recognition rate by controlling the output of the RF signal, and may have excellent performance in heat generation and power.

2 is a block diagram illustrating the configuration of an electronic device according to an embodiment of the present invention.

The electronic device 110 according to an embodiment may transmit/receive an RF signal to/from the external device 120 . The electronic device 110 according to an embodiment may include an antenna 210 , an RF modem 220 , a processor 232 , and a proximity sensor 240 .

According to an embodiment, the antenna 210 may transmit/receive an RF signal. Transmission and reception performed by the antenna 210 may be performed according to the control of the RF modem 220 or information provided by the RF modem. In one embodiment, the antenna 210 may generally transmit and/or receive RF signals with an external device. The antenna 210 may have various structures, and may be, for example, a loop-type antenna. The antenna 210 may include any known structure. For example, antenna 210 may include a known NFC antenna structure.

The antenna 210 may transmit/receive an RF signal in the form of electromagnetic waves, and the power of the signal may be controlled by the processor 232 . The output strength is the energy per unit time of the transmitted RF signal and is related to the amplitude of the electromagnetic wave. Adjustment of the output intensity may be performed by various methods. For example, the antenna 210 may include an amplifier, and may be configured to control the amplifier to adjust the output strength of the RF signal.

The RF modem 220 may control to transmit/receive an RF signal through the antenna 210 . For example, as a configuration capable of reading and writing a signal according to the NFC protocol, it may include a known NFC serial EEPROM. The RF modem 220 may provide information to the antenna 210 so that the antenna 210 transmits/receives a signal, or may control the antenna 210 by including a processing device such as a CPU. The RF modem 220 may transmit/receive an RF signal through the antenna 210 under the control of the processor 232 . For example, the RF modem 220 may control the antenna to transmit and receive an initial command NFC signal under the control of the processor 232 , so that the electronic device 110 functions as an initiator.

The processor 232 according to an embodiment is a component that plays a pivotal role when the electronic device 110 transmits and receives an RF signal. In an embodiment, the processor 232 may control the RF modem 220 so that the electronic device 110 transmits an RF signal.

According to an embodiment, the processor 232 receives the detection signal through the proximity sensor 240, and controls the RF modem 220 to transmit the RF signal to the external device 120 with a first strength, It is determined whether a response signal to the RF signal is received from the external device 120 , and as a result of the determination, when the response signal is not received, the RF signal to the external device 120 at a second intensity greater than the first intensity It is possible to control the RF modem 220 to transmit.

The processor 232 may control the output strength of the RF signal transmitted by the antenna 210 . Here, the control includes indirectly controlling by controlling the RF modem 220 . For example, the processor 232 transmits strength information of an RF signal to be transmitted to the RF modem 220 , and the RF modem 220 controls the amplifier of the antenna 210 according to the strength information, or uses the strength information to the amplifier. , and the antenna 210 may be configured to transmit an RF signal with a corresponding strength.

The intensity of the output of the transmitted RF signal may be controlled to gradually increase from the low level of the first intensity. Here, the first intensity is an output intensity for transmitting an RF signal and refers to an initial value. That is, the antenna 210 may start transmitting the RF signal with the first strength.

The processor 232 may determine whether a response signal has been received from the external device 120 prior to increasing the intensity of the output. The processor 232 may be configured to increase the strength of the output when a response signal is not received. The process of determining whether or not a response signal is received, and if not received, may repeat the process of transmitting with a greater strength than the previous strength. The output intensity may be repeated until the maximum output intensity is reached.

When the response signal is received, the antenna output strength may not be increased. Since the communication has reached a sufficient strength, it is possible to continue communication with the corresponding output strength without further increasing the output strength. The output intensity may be stored in the memory 234 .

The increase in output may be made by dividing the section. It can be increased through several steps by reducing the interval interval, and can be increased through small steps by increasing the interval interval. The interval interval may be variously set. The interval intervals are not the same and may be set differently. The interval may be configured to increase arithmetically or may be configured to increase exponentially.

According to an embodiment, the first intensity may be a quarter of the maximum output intensity. Furthermore, the processor 232 may control the output intensity of the antenna 210 to be increased by one quarter of the maximum output intensity.

According to another embodiment, the first intensity may be stored in a memory 234 of the MCU 230 or a memory (not shown) configured in the RF modem 220 or a program. The preset reference output intensity may be stored, and the reference output intensity may be read when a signal is transmitted and used as the first intensity.

According to an embodiment, the processor 232 may be configured in the electronic device 110 as the MCU 230 together with the memory 234 . The MCU 230 may be a device including a CPU, a memory, and an input/output, and may be configured as one chip, component, or electronic circuit, or may be a combination of a chip, component, or electronic circuit.

According to an embodiment, the memory 234 is a configuration for storing information, and may include at least one of a RAM, a ROM, and a FLASH memory. In one embodiment, the memory may store the reference output intensity.

The external device 120 may also be a device that transmits an RF signal. For example, it may be an active NFC device. The electronic device 110 may receive an RF signal from the external device 120 . For example, communication may be performed by receiving an initial command (Initiating) signal from an external device that is an active NFC device.

In this case, the intensity of the signal received by the electronic device 110 may be measured and used as the first intensity of the RF signal to be output. When the strength of the received signal is stored in the memory 234 as the reference output strength, and the processor 232 controls the antenna 210 to output the RF signal, the reference output strength stored in the memory 234 is read and the first The intensity can be controlled.

When the proximity sensor 240 detects an external device 120 approaching within a predetermined distance and starts transmitting an RF signal, it can detect the external device and transmit the RF signal after waiting a predetermined time. When a signal is received from the external device 120 within the waiting time, it may be configured to store the strength of the received signal in a memory and start transmitting the RF signal using the first strength as the first strength.

If the electronic device 110 recognizes the signal transmitted from the external device 120 well, it can be reasonably predicted that the recognition rate can be increased by transmitting the RF signal near the strength of the corresponding signal. Therefore, since there is no need to attempt to decrease the strength of the received signal, the strength of the received signal may be taken as the first strength, and an appropriate output strength may be found while gradually increasing the strength. By using the strength of a signal received and recognized from an external device as the first strength, it is possible to shorten the time to find an appropriate signal output strength. Ultimately, this has the effect of speeding up the recognition speed.

According to an embodiment, the proximity sensor 240 may detect an object approaching a predetermined distance or less. Furthermore, the proximity sensor 240 may transmit the sensed signal to the processor 232 . The proximity sensor 240 may use a known sensor.

In an embodiment, the predetermined distance may be set as a parameter of the proximity sensor 240 . A predetermined distance at which the proximity sensor 240 detects an approaching object may be set according to a signal transmitted by the electronic device. For example, since NFC communicates at 10 cm or less, the proximity sensor 240 may be set to detect only objects approaching within the corresponding distance by setting a predetermined distance to 10 cm or less. When the object approaches within a set predetermined distance, the proximity sensor 240 may transmit a detection signal to the processor.

The processor 232 may be configured to start transmitting an RF signal through the antenna 210 when receiving a detection signal from the proximity sensor 240 . That is, when an external device approaches and the proximity sensor 240 detects it, the electronic device 110 may be configured to start emitting an RF signal while increasing the output from a small intensity.

Even if the electronic device 110 does not transmit the RF signal at the maximum output from the beginning according to an embodiment and gradually increases it from the low output, if there is no communication target terminal in the vicinity or is not detected, ultimately transmit the signal at the maximum output A problem remains That is, if there is no external device to transmit a response signal so that the processor does not further increase the increase in output strength, the output may converge to the maximum output.

This problem can be solved by starting the RF signal transmission when the proximity sensor 240 recognizes the external device 120 . When the external device 120 receives the RF signal and confirms that it exists at a communication distance, the electronic device 110 starts to transmit the signal of the first intensity, so that it does not receive a response signal in the output control process and eventually It has the effect of solving the problem of reaching the maximum output. In addition, there is an effect of not generating heat, an increase in power consumption, and unnecessary noise in surrounding electronic devices.

According to an embodiment, the noise analyzer 250 may receive an RF signal including noise from the antenna 210 , analyze the noise, and transmit the analysis result to the processor 232 . The RF signal received by the noise analyzer 250 may include a signal transmitted by the antenna 210 and external noise. As an example of noise analysis, it is possible to analyze whether a frequency is misaligned. Alternatively, the waveform of the signal may be analyzed.

The noise analyzer 250 may analyze the frequency or analyze the frequency shift itself. For example, it is possible to analyze how much the frequency of the signal is, and determine whether the frequency is 13.56Mhz. The noise analyzer 250 may include known configurations.

3 is a flowchart illustrating a method for controlling an output of an RF signal by an electronic device according to an embodiment of the present invention. A method for the electronic device 110 to control the output of an RF signal according to an embodiment includes: receiving a detection signal detecting the approach of the external device 120 through the proximity sensor 240 ; transmitting an RF signal to an external device 120 at a first intensity; determining whether a response signal to the RF signal is received from the external device 120; If it is determined that the response signal is not received, transmitting the RF signal to the external device 120 with a second intensity greater than the first intensity.

The method by which the electronic device 110 controls the output of the RF signal according to an embodiment may start with receiving a detection signal for detecting the approach of the external device 120 through the proximity sensor 240 . (S310). The electronic device may be configured to transmit an RF signal regardless of whether there is an external device nearby, but when the processor 232 is configured to start transmitting an RF signal when the detection signal is received through the proximity sensor 240 As described above, the output can be more effectively controlled.

Next, a step of transmitting the RF signal to the external device 120 with the first strength may be performed (S320). This may be performed by the antenna 210 under the control of the processor 232 , and the RF signal may be controlled to be transmitted as an output of the first intensity, which is an initial value. The first century is the same as described above.

After starting to transmit the RF signal at the first strength, a step of determining whether a response signal to the RF signal is received from the external device 120 may be performed (S330). When the response signal is not received, the electronic device 110 may transmit the RF signal with a second intensity greater than the first intensity (S340). It can be increased by dividing it into several discrete levels, or the intensity can be gradually increased to be close to continuous. The output intensity does not necessarily have to increase in the entire section, but the overall trend may increase, and preferably increase in an increasing function.

The process of determining whether or not a response signal is received, and if not received, may repeat the process of transmitting with a greater strength than the previous strength. The output intensity may be repeated until the maximum output intensity is reached. For example, the RF signal is transmitted by setting the first intensity to a quarter of the maximum output intensity, it is determined whether a response signal is received, and if there is no response signal received, the process of increasing by one quarter is repeated. can be configured to

When there is an external device 120 that is a counterpart receiving the RF signal transmitted by the electronic device 110 and receives a response signal from the external device, the increase in the antenna output strength may be terminated. Since the communication has reached a sufficient strength, it is possible to continue communication with the corresponding output strength without further increasing the output strength. The output intensity may be stored in the memory 234 .

Since the corresponding output strength can be viewed as the minimum output strength at which communication can be performed smoothly, the output control method according to an embodiment of the present invention unconditionally transmits the maximum output signal as in the prior art, resulting in poor recognition, heat generation, and power consumption. is effective in solving the problem of

4 is a flowchart illustrating a method of correcting a frequency of an RF signal by an electronic device according to an embodiment of the present invention.

First, the noise analyzer 250 may perform a step of receiving the RF signal (S410). The RF signal received here may include a signal transmitted by the antenna 210 of the electronic device 110 and external noise.

Next, the noise analyzer 250 may analyze the frequency shift of the RF signal (S420). Even when the electronic device 110 transmits a signal of a frequency to be transmitted, the signal is deformed when noise is included to cause interference. Not only the waveform is deformed by the noise, but also the frequency is distorted. For example, since NFC communicates at 13.56Mhz, the electronic device 110 transmits 13.56Mhz, but if the frequency is changed due to noise, the external device that receives the signal eventually receives the signal of the wrong frequency instead of 13.56Mhz will receive This will interfere with smooth communication. The noise analyzer 250 may analyze the signal of the antenna 210 and analyze the frequency to determine whether there is a frequency shift.

When it is determined that there is a frequency shift, a step of controlling the RF modem to be corrected to the original frequency, that is, a desired frequency may be performed (S430). In consideration of a frequency shift due to noise, a signal including noise may be corrected to have an original frequency by changing a transmission frequency. For example, if the frequency is slightly increased than 13.56Mhz due to noise, the processor may correct the transmitting frequency to be slightly lower than 13.56Mhz so that the resulting frequency becomes the original frequency of 13.56Mhz.

By including the noise analyzer 250 , the electronic device 110 may solve a frequency shift phenomenon due to noise and improve a recognition rate to enable smooth communication. As described above, the electronic device 110 may increase the recognition rate by adjusting the output intensity of the transmitted RF signal, and may further increase the recognition rate by analyzing the frequency shift phenomenon and correcting the frequency of the RF signal.

Those skilled in the art to which the present invention pertains should understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential characteristics thereof, so the embodiments described above are illustrative in all respects and not restrictive. only do The scope of the present invention is indicated by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. .

110: electronic device
120: external device
210: antenna
220: RF modem
230 : MCU
232: processor
234 : memory
240: proximity sensor
250: noise analyzer

Claims (12)

In an electronic device,
a proximity sensor configured to detect an external device approaching within a predetermined distance;
an antenna configured to transmit and receive RF signals;
an RF modem for controlling transmission and reception of the RF signal through the antenna; and
a processor configured to control the RF modem;
The processor is
When receiving a detection signal through the proximity sensor,
controlling the RF modem to transmit the RF signal to the external device with a first strength;
It is determined whether a response signal to the RF signal is received from the external device,
When the response signal is not received as a result of the determination, the electronic device controls the RF modem to transmit the RF signal to the external device at a second intensity greater than the first intensity.
According to claim 1,
a memory configured to store data;
and the first intensity is a reference output intensity stored in the memory.
3. The method of claim 2,
The processor is
The electronic device is further configured to store, as the reference output strength, the strength of a signal received from the external device and recognized in the memory.
According to claim 1,
The processor is
It is determined whether a response signal to the RF signal is received from the external device, and as a result of the determination, when the response signal is not received, the RF signal is transmitted to the external device with an intensity greater than the previous intensity. An electronic device that repeats the process of controlling the RF modem until the intensity of the RF signal becomes the maximum output intensity.
5. The method of claim 4,
the first intensity is a quarter of the maximum output intensity,
The intensity greater than the previous century is,
an intensity increased by a quarter of the maximum output intensity over the previous intensity.
According to claim 1,
Further comprising a noise analyzer,
The noise analyzer analyzes the frequency shift of the RF signal and
The processor is
and controlling the RF modem to be corrected to the original frequency based on a result of the analysis.
A method for an electronic device to control the output of an RF signal, the method comprising:
Receiving a detection signal for detecting the approach of an external device through a proximity sensor;
transmitting the RF signal to the external device at a first intensity when receiving the detection signal;
determining whether a response signal to the RF signal is received from the external device;
and transmitting the RF signal to the external device at a second intensity greater than the first intensity when the response signal is not received as a result of the determination.
8. The method of claim 7,
wherein the first intensity is a reference output intensity stored in a memory.
9. The method of claim 8,
The method further comprising the step of storing the strength of the recognized signal received from the external device as the reference output strength in the memory.
8. The method of claim 7,
It is determined whether a response signal to the RF signal is received from the external device, and as a result of the determination, when the response signal is not received, the RF signal is transmitted to the external device with an intensity greater than the previous intensity. The method further comprising repeating the process until the strength of the RF signal is the maximum output strength.
11. The method of claim 10,
the first intensity is a quarter of the maximum output intensity,
The intensity greater than the previous century is,
an intensity increased by a quarter of the maximum output intensity over the previous intensity.
8. The method of claim 7,
analyzing the frequency shift of the RF signal;
Further comprising; correcting the original frequency based on the result of the analysis.

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