KR102111383B1 - Control device of adaptive receiver - Google Patents

Abstract

Disclosed is an invention for a control device of an adaptive receiver. The control device of the adaptive receiver of the present invention includes an RF receiver for receiving broadcast information of a currently broadcasted broadcast channel and adjacent broadcast channels adjacent to the broadcast channel, a GPS module for receiving a vehicle position, and an RF level according to the position Tuning the broadcast channel received through the storage unit that stores data and the RF receiver outputs a broadcast signal, and receives the location of the vehicle from RADIO DSP and the GPS module that provide noise data for the broadcast channel MCU that retrieves data on the RF level corresponding to the location of the vehicle from the storage unit, receives the noise data from the RADIO DSP, and selects and transmits tuning data from the data on the RF level and the noise data It characterized in that it comprises.

Description

CONTROL DEVICE OF ADAPTIVE RECEIVER

The present invention relates to a control device of an adaptive receiver, and more specifically, to grasp the position of a vehicle through a GPS module and to broadcast by actively changing the conditions of the receiver in consideration of the changing radio environment according to the identified vehicle position. It relates to a control device of an adaptive receiver to optimize the reception performance.

In general, a broadcast receiver estimates an RF level of a broadcast signal input to an antenna in real time to determine a channel state and reception performance of a broadcast.

That is, through the output of the accumulator in the automatic gain control (AGC) device, the RF level of the broadcast signal is simply transmitted, and the reception performance is changed by changing the H / W (R, L, C) of the tuner. Is optimizing.

In other words, since the current frequency or the level of the broadcast channel is measured and transmitted to the receiver, information on the broadcast channel can be obtained.

However, in the case of an antenna used in an actual vehicle, since it uses an ACTIVE antenna, unlike an ordinary communication terminal that applies a PASSIVE antenna, it is easily saturated by adjacent strong field signals of a channel currently being broadcast, so that it is impossible to restore the data of a listening broadcast. Can occur.

Therefore, there is a need to develop a device that operates in such a way that it does not affect broadcast reception by adjusting the gain (GAIN) of the antenna by scanning the surrounding electric field levels in real time before the vehicle antenna is saturated.

Background of the invention is disclosed in Republic of Korea Patent Publication No. 10-2011-0100781 (2011. 09. 15. published, the name of the invention: a vehicle radio broadcast receiver and its frequency automatic switching method).

The present invention was created by the necessity as described above, and the object of the present invention is to determine the position of the vehicle through the GPS module and actively change the conditions of the receiver in consideration of the changing radio environment according to the identified vehicle position. It is to provide a control device of an adaptive receiver that optimizes broadcast reception performance.

Another object of the present invention is to improve the reception performance of adjacent channels in consideration of the changing radio environment by region and time, but suppress the saturation of the antenna in advance in the strong field region, and change the RF level and noise in the weak field region. It is to provide a control device of an adaptive receiver that improves the performance of a broadcast receiver by sensing and reflecting data optimally tuned to external conditions in real time.

The apparatus for controlling an adaptive receiver according to the present invention includes: an RF receiver for receiving broadcast information of a currently broadcasted broadcast channel and adjacent broadcast channels adjacent to the broadcast channel; GPS module for receiving the location of the vehicle; A storage unit that stores data for the RF level according to the location; A RADIO DSP that tunes the broadcast channel received through the RF receiver to output a broadcast signal and provides noise data for the broadcast channel; And receiving the location of the vehicle from the GPS module, retrieving data for the RF level corresponding to the location of the vehicle in the storage unit, receiving the noise data from the RADIO DSP, and receiving the data for the retrieved RF level. An MCU that selects and transmits tuning data from the noise data; It characterized in that it comprises.

In the present invention, the RF receiving unit is characterized in that it comprises a first receiving unit for receiving the current broadcast channel and a second receiving unit for receiving the frequency and RF level of the adjacent broadcast channel adjacent to the broadcast channel.

In the present invention, the MCU is characterized in that it receives the data for the RF level corresponding to the position of the vehicle and the noise data in real time and transmits the selected tuning data to the RADIO DSP in real time.

In the present invention, the RADIO DSP is characterized by tuning by reflecting the tuning data transmitted from the MCU.

In the present invention, the storage unit is characterized in that it is divided into a strong electric field, a weak electric field, a multi-pass, and interference according to the location, and stores data for each RF level.

The control device of the adaptive receiver according to the present invention determines the position of the vehicle through the GPS module, and actively adjusts the conditions of the receiver in consideration of the changing radio environment according to the identified vehicle position, so that broadcast reception performance is optimized. Can be.

In addition, the reception performance of adjacent channels is improved in consideration of the changing radio environment by region and time, but the saturation of the antenna is suppressed in advance in the strong electric field region, and the RF level and noise change are detected in the weak electric field region to detect external conditions. By allowing optimally tuned data to be reflected in real time, the performance of the broadcast receiver can be improved to maximize customer satisfaction.

1 is a block diagram showing a control apparatus of an adaptive receiver according to an embodiment of the present invention.
2 to 3 are graphs showing a broadcast channel spectrum according to an RF level in a control device of an adaptive receiver according to an embodiment of the present invention.
4 is an exemplary view showing a broadcast service available area according to a transmitter location for each frequency in a control device of an adaptive receiver according to an embodiment of the present invention.

Hereinafter, a control apparatus of an adaptive receiver according to an embodiment of the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or practice. Therefore, the definition of these terms should be made based on the contents throughout the specification.

1 is a block diagram showing a control apparatus of an adaptive receiver according to an embodiment of the present invention, and FIGS. 2 to 3 are broadcast according to RF levels in a control apparatus of an adaptive receiver according to an embodiment of the present invention. It is a graph showing the channel spectrum.

FIG. 2 shows a broadcast spectrum of a good electric field, and as shown in FIG. 2, uniform electric fields are distributed in A, B, and C channels, and in this case, all channels can receive good broadcast.

However, FIG. 3 shows a broadcast spectrum due to signal saturation in a strong electric field region. As shown in FIG. 3, saturation occurs when a C channel having a high RF level enters an antenna during broadcast reception of the B channel. Data is lost on channel B, and normal broadcast reception is not possible.

Therefore, in the case of the control device of the adaptive receiver according to the present invention, in order to improve the reception performance by actively optimizing the conditions of the receiver as shown in FIG. 3, tuning data is selected and reflected as follows.

As shown in Figure 1, the control device of the adaptive receiver according to an embodiment of the present invention, RF receiving unit 10, GPS module 20, storage unit 30, MCU 40 and RADIO DSP 50 Includes.

The RF receiver 10 receives a broadcast channel currently being broadcast, receives a frequency and an RF level of a neighboring broadcast channel adjacent to the current broadcast channel, and receives RF signal strength indicator (RSSI) information of the current broadcast channel. do.

At this time, the RF receiver 10 is composed of a channel for broadcast reception, a channel for channel scanning, that is, a dual channel, and in detail, a first receiver for receiving a current broadcast channel and a broadcast channel adjacent to the current broadcast channel It consists of a second receiver for receiving the frequency and RF level of the.

In addition, the RF receiver 10 includes logic to determine the RF level, and continuously transmits the received signal strength (RSSI, RF Signal Strength Indicator) information of the current broadcast channel to the micro control unit (MCU) 40.

In addition, data transmission may be performed at least every 200 ms to determine level information in a real vehicle.

The GPS module 20 receives the location of the vehicle and the current time.

The storage unit 30 stores data for the RF level according to the location.

In detail, according to the distance from the current vehicle position (receiver position) to the transmitter, it can be divided into strong electric field, weak electric field, multi-pass and interference, respectively, and stores data on the RF level of each electric field.

The RADIO DSP 50 tunes a broadcast channel received through the RF receiver 10 to output a broadcast signal, and provides noise data for the broadcast channel.

That is, when a broadcast is received through audio and AVN, noise data for the environment surrounding the RADIO DSP 50 is generated and provided to the MCU 40.

 MCU 40 receives the location of the vehicle from the GPS module 20, the storage unit 30 retrieves the data for the RF level corresponding to the location of the vehicle transmitted from the GPS module 20, RADIO DSP (50 ) Receives noise data for the current broadcast channel, selects tuning data from the data and noise data for the searched RF level, and transmits it to the RADIO DSP (50).

In this case, the storage unit 30 may store a table in which the tuning data reflection reference value for each electric field is set as shown in Table 1 below.

Electric field
division tuning
data RF level and noise RF level (dBuV) USN (%) Multipass (%) Modulation (kHz) Strong electric field X 30-50 0 ~ 10 0 to 20 0 ~ 40 Weak electric field Y 10 to 30 20 to 30 20 to 30 0 ~ 25 Multi pass Z 20 to 30 10 to 30 30-50 20 to 30 Whole body W 0 ~ 30 30 to 40 20 to 30 0 ~ 40

Here, X, Y, Z, and W are tuning data for each electric field optimized for RF level and noise.

Therefore, the MCU 40 selects the electric field by grasping the location of the vehicle, and selects tuning data by referring to the RF level and noise value according to the electric field.

At this time, the MCU 40 may receive the RF level data and noise data corresponding to the position of the vehicle in real time and transmit the selected tuning data to the RADIO DSP 50 in real time.

Therefore, even if the position of the vehicle changes, it is possible to prevent the reception performance from deteriorating by selecting and reflecting the optimized tuning data.

In addition, the RADIO DSP 50 reflects the tuning data transmitted from the MCU 40 so that the broadcast tuned with the optimal performance is output through the amplifier 60 and the speaker 70.

In addition, an AGC (Automatic Gain Control) control unit for suppressing the RF input signal of the strong field may be further provided.

At this time, the AGC control unit determines the electric field level received from the MCU 40, and when the determined electric field level is a level exceeding the reference saturation point, it uses the general purpose input / output pin (GPIO) of the MCU 40 to LOW / HIGH can be controlled.

Specifically, when the GPIO status is 0, the AGC is not controlled, and when the antenna AGC is driven, the GPIO is set to 1 to operate the AGC. If the electric field level becomes low, the antenna can be set to operate in the ACTIVE state by converting the GPIO state from 1 to 0 so that the original GAIN can be maintained.

4 is an exemplary view showing a broadcast service available area according to a transmitter location for each frequency in a control device of an adaptive receiver according to an embodiment of the present invention.

That is, electric fields may be divided into strong electric field, heavy electric field, and weak electric field according to the position of the vehicle based on the transmitter, and the present invention does not degrade broadcast reception performance in a vehicle that changes in real time by reflecting tuning data tuned for each electric field. Do not.

As described above, the control device of the adaptive receiver according to the embodiment of the present invention, the control device of the adaptive receiver identifies the position of the vehicle through the GPS module, and considers the changing radio environment according to the identified vehicle position. Thus, the broadcast reception performance can be optimized by actively changing the conditions of the receiver.

In addition, the reception performance of adjacent channels is improved in consideration of the changing radio environment by region and time, but the saturation of the antenna is suppressed in advance in the strong electric field region, and the RF level and noise change are detected in the weak electric field region to detect external conditions. By allowing optimally tuned data to be reflected in real time, the performance of the broadcast receiver can be improved to maximize customer satisfaction.

The present invention has been described with reference to the embodiment shown in the drawings, but this is only exemplary, and those skilled in the art to which the art belongs understand that various modifications and other equivalent embodiments are possible therefrom. will be. Therefore, the true technical protection scope of the present invention should be defined by the following claims.

10: RF receiver 20: GPS module
30: storage unit 40: MCU
50: RADIO DSP 60: amplifier
70: speaker

Claims (5)

An RF receiver for receiving broadcast information of a currently broadcasted broadcast channel and adjacent broadcast channels adjacent to the broadcast channel;
GPS module for receiving the location of the vehicle;
A storage unit that stores data for the RF level according to the location;
A RADIO DSP that tunes the broadcast channel received through the RF receiver to output a broadcast signal and provides noise data for the broadcast channel; And
Received the location of the vehicle from the GPS module, the storage unit retrieves data on the RF level corresponding to the location of the vehicle, receives the noise data from the RADIO DSP, and retrieves the data on the RF level. An MCU that selects and transmits tuning data for optimizing broadcast reception performance from the noise data; Including,
The MCU
RF data corresponding to the position of the vehicle and the noise data are provided in real time and the selected tuning data is transmitted to the RADIO DSP in real time,
The RADIO DSP
Tuning a broadcast channel by reflecting the tuning data transmitted from the MCU,
The storage unit
Control device for an adaptive receiver, characterized in that the electric field is divided into a strong electric field, a weak electric field, a multipath, and interference according to the location, and data for RF levels in each electric field is stored.
The method of claim 1, wherein the RF receiver
And a first receiver for receiving the currently broadcasted broadcast channel and a second receiver for receiving the frequency and RF level of adjacent broadcast channels adjacent to the broadcast channel.
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