KR101334063B1 - Method for comprising internet protocol packet for monitoring and controlling rf signal of femtocell apparatus remotely - Google Patents

Abstract

The present invention provides a method for generating an internet protocol packet for remotely controlling and monitoring RF signals of a femtocell device, the method comprising the following steps. Packet enable signals are positioned. Operation flag signals are positioned after the packet enable signals. RF data sequence signals are positioned after the operation flag signals. RF data digital signals are positioned after the RF data sequence signals. [Reference numerals] (AA) PSE equipment;(BB) Remote monitoring server;(CC) Collect SE data

Description

METHOD FOR COMPRISING INTERNET PROTOCOL PACKET FOR MONITORING AND CONTROLLING RF SIGNAL OF FEMTOCELL APPARATUS REMOTELY}

The present invention relates to a method for generating an internet protocol packet for remote monitoring and control of an RF signal of a femtocell device, and more particularly, to receive an RF signal radiated from a femtocell device and converting the RF signal into an RF data digital signal. A femtocell device capable of effectively monitoring and controlling a femtocell device remotely by generating an internet protocol packet including a signal and transmitting it to a remote monitoring server through an internet network and receiving a corresponding internet protocol packet from the remote monitoring server. The present invention relates to an internet protocol packet generation method for remote monitoring and control of RF signals.

Recently, due to the explosion of mobile traffic, there is an increasing demand for a femtocell system that can effectively inject mobile traffic in mobile communication networks such as the latest LTE (Long Term Evolution) system due to the overload of the system and the deterioration of service quality.

Meanwhile, in Patent Publication No. 10-2011-0126160, in order to guarantee the normal operation of the femtocell device, the integrity of the femtocell is verified through a hash-based encrypted file transmission remotely, but the location of the femtocell device is changed and the appearance of a new wireless obstacle. When the femtocell device's performance is deteriorated due to changes in the wireless environment, there is a problem in that such performance degradation cannot be effectively monitored or controlled.

Therefore, the technical problem to be achieved by the present invention is to generate the Internet protocol packet for remote monitoring and control of the RF signal of the femtocell device that can effectively monitor or control the performance degradation when the performance of the femtocell device is degraded due to changes in the wireless environment. To provide a way.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise forms disclosed. Other objects, which will be apparent to those skilled in the art, It will be possible.

In order to achieve the above object, an internet protocol packet generation method for remote monitoring and controlling RF signals of a femtocell device according to an embodiment of the present invention may include: disposing a packet enable signal, and operating after the packet enable signal Disposing a flag signal, disposing an RF data sequence signal after the operation flag signal, and disposing an RF data digital signal after the RF data sequence signal.

In the method for generating an internet protocol packet for remote monitoring and controlling RF signals of a femtocell device according to an embodiment of the present invention, in the disposing of the packet enable signal, the packet enable signal may be any one of 41 to 255. It is desirable to choose.

In the method for generating an internet protocol packet for remote monitoring and control of an RF signal of a femtocell device according to an embodiment of the present invention, in the disposing of the operation flag signal, the operation flag signal may be an RF data response signal and an RF data preparation. It is preferable to select one of the signal and the RF data payload signal of the sequence number.

According to an embodiment of the present invention, a method for generating an internet protocol packet for remote monitoring and controlling an RF signal of a femtocell device may include disposing the packet enable signal between the packet enable signal and the operation flag signal. Preferably, the method further includes disposing a packet enable acknowledgment signal.

In the method for generating an internet protocol packet for remote monitoring and controlling an RF signal of a femtocell device according to an embodiment of the present invention, in the disposing of the packet enable acknowledgment signal, the packet enable acknowledgment signal may be any one of 1 to 255. It is preferable to choose one.

In the method for generating an internet protocol packet for remote monitoring and controlling an RF signal of a femtocell device according to an embodiment of the present invention, in the disposing of the operation flag signal, the operation flag signal may be a power off execution signal of a power supply equipment or It is preferable to further include a power-on execution signal of the power supply equipment.

According to another aspect of the present invention, there is provided a method for generating an internet protocol packet for remote monitoring and controlling an RF signal of a femtocell device according to another embodiment of the present invention, including disposing a packet enable signal and an operation flag after the packet enable signal. Disposing a signal and disposing an RF data time stamp signal after the operation flag signal.

Internet protocol packet generation method for the RF signal remote monitoring and control of the femtocell device according to another embodiment of the present invention, in the step of disposing the packet enable signal, the packet enable signal is any one of 41 ~ 255 It is desirable to choose.

According to another aspect of the present invention, there is provided a method for generating an internet protocol packet for remote monitoring and control of an RF signal of a femtocell device by arranging the operation flag signal, wherein the operation flag signal is an RF data start time stamp transmission signal or RF signal. It is preferable to select one of the data end time stamp transmission signals.

According to another embodiment of the present invention, a method for generating an internet protocol packet for remote monitoring and controlling an RF signal of a femtocell device may include disposing the packet enable signal between the packet enable signal and the operation flag signal. Preferably, the method further includes disposing a packet enable acknowledgment signal.

In the method for generating an internet protocol packet for remote monitoring and control of an RF signal of a femtocell device according to another embodiment of the present invention, in the disposing of the packet enable acknowledgment signal, the packet enable acknowledgment signal may be any one of 1 to 255. It is preferable to choose one.

Internet protocol packet generation method for remote monitoring and control of the RF signal of the femtocell device according to embodiments of the present invention, when the performance of the femtocell device is degraded due to changes in the wireless environment, the Internet protocol including the RF signal of the femtocell device By generating the packet and transmitting it to the remote monitoring server through the Internet network, and receiving the corresponding Internet protocol packet from the remote monitoring server, it is possible to effectively monitor or control such a performance degradation.

1 is a configuration of a femtocell system to which the Internet protocol packet generation methods for remote monitoring and control RF signal of a femtocell device according to embodiments of the present invention.
2 is a detailed configuration diagram of the power supply equipment of FIG.
3 is a structure diagram of a bit string of an internet protocol packet used in an internet protocol packet generation method for RF signal remote monitoring and control of a femtocell device according to embodiments of the present invention.
4 is a structural diagram of a bit string of an Internet protocol packet transmitted from a remote monitoring server in response to the Internet protocol packet of FIG.
5 is a signal flow diagram between a power supply equipment and a remote monitoring server to which the Internet protocol packet generation method for RF signal remote monitoring and control of a femtocell device according to embodiments of the present invention is applied.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The details of other embodiments are included in the detailed description and drawings. BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. Like reference numerals refer to like elements throughout the specification.

1 is a configuration diagram of a femtocell system to which Internet protocol packet generation methods for remote monitoring and controlling RF signals of a femtocell device according to embodiments of the present invention are applied, and FIG. 2 is a detailed configuration diagram of a power supply device of FIG. 1. 3 is a structural diagram of a bit string of an internet protocol packet used in an internet protocol packet generation method for RF signal remote monitoring and control of a femtocell device according to embodiments of the present invention, and FIG. 4 is a block diagram of the internet protocol packet of FIG. Correspondingly, it is a structure diagram of a bit string of an internet protocol packet transmitted from a remote monitoring server, and FIG. 5 is a power supply equipment to which an internet protocol packet generation method is applied for RF signal remote monitoring and control of a femtocell device according to embodiments of the present invention. Is a signal flow between a remote monitoring server.

As shown in FIG. 1, a femtocell system includes a femtocell device 1000, a power supply equipment (PSE) 2000, an internet network 3000, a femtocell gateway 4000, and a remote monitoring server 5000. .

The power supply device 2000 transmits power and Ethernet data to the femtocell device 1000 through an Ethernet interface, generates an Internet protocol packet for remote monitoring and control of the RF signal of the femtocell device, and transmits it to the Internet network 3000. The transmitted internet protocol packet is transmitted to the remote monitoring server 5000 through the femtocell gateway 4000.

The RF data packet processing unit 5100 of the remote monitoring server 5000 obtains the RF data digital signal from the Internet protocol packet transmitted from the power supply equipment 2000, and transmits the RF data digital signal to the RF signal processing unit 5200, and the RF signal processing unit 5200. ) Converts the received RF data digital signal into an analog signal and provides information for analyzing a situation of a wireless environment of the femtocell device 1000. The RF signal processor 5200 controls the RF data packet processor 5100 to cut off the power of the power supply equipment 2000 when the converted RF analog signal is less than or equal to the reference value, thereby remotely initializing the femtocell apparatus 1000. You can perform a reboot.

Here, the power supply equipment 2000 is a power supply for transmitting power or Ethernet data to the femtocell device 1000 and the Ethernet communication unit 2100, a power supply unit 2200 for supplying power to the power and Ethernet communication unit 2100, power And a clock supply unit 2300 for supplying an IEEE 1588 clock to the Ethernet communication unit 2100, an RF transceiver 2400 for receiving an RF signal radiated from the femtocell device 1000, and converting the RF signal into an RF data digital signal. And a packet generator 2500 for generating an internet protocol packet including an RF data digital signal provided from the RF data digital signal.

3 and 4, the structure of the Internet protocol packet generated in the embodiments of the present invention will be described.

Internet protocol packets generated in the embodiments of the present invention follow the ICMP (Internet Control Message Protocol) format, but unlike the general ICMP scheme, as described below, they constitute a packet.

First, an 8-bit string indicating an ICMP packet type is arranged as a packet enable signal (Enable) in the present invention. Here, the packet enable signal (Enable) selects any one of 41 to 255, which is a reserved value in the ICMP scheme, and FIG. 3 shows 0xF0, which is a hexadecimal number of 240.

Next, after the packet enable signal Enable, an 8-bit code signal indicating a packet state and a 16-bit checksum signal Checksum for checking an error are disposed.

Subsequently, a packet enable acknowledgment signal ID is disposed, and the packet enable acknowledgment ID selects any one of 1 to 255. 3 shows 0xFE, which is a 254 hexadecimal number.

The power supply device 2000 also transmits a packet enable signal (Enable), a code signal (Code), a checksum signal (Checksum), and a packet enable confirmation signal (ID) of the Internet protocol packet transmitted by the remote monitoring server 5000. Is set in the same manner as the Internet protocol packet.

Detailed operations will be described later with reference to FIG. 5.

First, the remote monitoring server 5000 sets the 0x01 indicating the RF data request signal to the operation flag signal Control Flag and transmits it to the power supply equipment 2000.

Next, the power supply equipment 2000 sets 0x02 indicating the RF data response in the operation flag signal and transmits it to the remote monitoring server 5000.

Next, when the power supply equipment 2000 is ready to transmit the Internet protocol packet including the RF data digital signal, the power supply equipment 2000 is ready for the RF data transmission signal (RF Data) to the operation flag signal (Control Flag) Set to 0x03 indicating Ready to Send to send.

Next, the remote monitoring server 5000 sets the operation flag signal (Control Flag) to 0x04 indicating an RF data request with sequence number of the sequence number, and after 0xFE, the RF data sequence signal (RF Data). Sequence and arrange.

Here, when the RF data sequence signal (RF Data Sequence) is set to 0, it can be configured to request the RF data digital signals of all sequence numbers.

Therefore, when the RF data sequence signal (RF Data Sequence) is set to 0, the power supply equipment 2000 sets the operation flag signal (Control Flag) to 0x05 indicating the RF data starting time stamp transmission signal (RF Data Starting TimeStamp). After 0x05, the RF data start time stamp signal TimeStamp is arranged and transmitted.

Next, the power supply equipment 2000 sets the operation flag signal (Control Flag) to 0x06 indicating the RF data payload signal (RF Data Payload with Sequence Number) of the sequence number, and after the 0x06 corresponding RF data sequence signal ( The RF Data Sequence is disposed, and then the RF Data Payload is arranged and transmitted.

Next, the power supply equipment 2000 sets the operation flag signal (Control Flag) to 0x06 indicating the RF data payload signal (RF Data Payload with Sequence Number) of the sequence number, and after 0x06 the next RF data sequence signal ( The RF Data Sequence is arranged, and then the next RF Data Payload is arranged and transmitted, and the above-described operation is sequentially performed up to the last sequence number.

Next, the power supply equipment 2000 sets the operation data signal (Control Flag) to 0x07 indicating the RF data end time stamp transmission signal (RF Data Ending TimeStamp), and after 0x07 the RF data end time stamp signal (TimeStamp) Send it by placing it.

On the other hand, when the RF data sequence signal (RF Data Sequence) is set to non-zero, the power supply equipment 2000 is the RF data payload signal (RF Data Payload with Sequence Number) of the sequence number in the operation flag signal (Control Flag) It is set to 0x06, which indicates that the RF data sequence signal (RF Data Sequence) is arranged after 0x06, and then the RF data payload is arranged and transmitted.

Here, the remote monitoring server 5000 analyzes the situation of the wireless environment of the femtocell device 1000 by acquiring RF data payload from the Internet protocol packet transmitted from the power supply equipment 2000. As a result, it may be controlled to cut off the power of the power supply equipment 2000.

Specifically, the remote monitoring server 5000 sets and transmits 0x08 indicating a PSE Power OFF Request signal of the power supply equipment 2000 to the operation flag signal Control Flag.

Next, the power supply equipment 2000 receives the power off request signal (PSE Power OFF Request) of the power supply equipment 2000 from the remote monitoring server 5000, and performs the power off for the femtocell device 1000. Afterwards, the power supply equipment 2000 sets and transmits 0x09 indicating the power off execution signal PSE Power OFF Committed of the power supply equipment 2000 to the operation flag signal Control Flag.

Next, the remote monitoring server 5000 sets and transmits 0x0C indicating a power off acknowledgment signal (PSE Power OFF Accepted) of the power supply equipment 2000 to the operation flag signal Control Flag.

Next, the remote monitoring server 5000 sets and transmits 0x0A indicating a PSE Power ON Request signal of the power supply equipment 2000 to the operation flag signal Control Flag.

Next, the power supply equipment 2000 receives the PSE Power ON Request signal of the power supply equipment 2000 from the remote monitoring server 5000, and performs power supply to the femtocell apparatus 1000. After that, the power supply equipment 2000 sets and transmits 0x0B indicating a power-on execution signal PSE Power ON Committed of the power supply equipment 2000 to the operation flag signal Control Flag.

Next, the remote monitoring server 5000 sets and transmits to the operation flag signal Control Flag as 0x0D indicating the PSE Power ON Accepted signal of the power supply equipment 2000.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

Rather, those skilled in the art will appreciate that many modifications and variations of the present invention are possible without departing from the spirit and scope of the appended claims.

Accordingly, all such appropriate modifications and changes, and equivalents thereof, should be regarded as within the scope of the present invention.

1000: femtocell device
2000: Power Supply Equipment
3000: Internet Network
4000: femtocell gateway
5000: remote monitoring server

Claims (11)

Placing a packet enable signal;
Disposing an operation flag signal after the packet enable signal;
Disposing an RF data sequence signal after the operation flag signal; And
And disposing an RF data digital signal after the RF data sequence signal. The Internet protocol packet generation method for remote monitoring and controlling RF signals of a femtocell device.
The method of claim 1,
In the step of disposing the packet enable signal, the packet enable signal is selected from any one of 41 ~ 255 Internet protocol packet generation method for remote monitoring and control of the RF signal of the femtocell device.
The method of claim 1,
In the disposing of the operation flag signal, the operation flag signal selects any one of an RF data response signal, an RF data transmission ready signal, and an RF data payload signal having a sequence number. How to generate internet protocol packets for monitoring and control.
3. The method of claim 2,
And disposing a packet enable acknowledgment signal between the packet enable signal and the operation flag signal after disposing the packet enable signal. Internet protocol packet generation method for a.
5. The method of claim 4,
In the disposing of the packet enable acknowledgment signal, the packet enable acknowledgment signal selects any one of 1 to 255.
The method of claim 3,
In the disposing of the operation flag signal, the operation flag signal may further include a power off execution signal of a power supply device or a power supply execution signal of a power supply device to monitor and control the RF signal of the femtocell device. Internet Protocol Packet Generation Method
Placing a packet enable signal;
Disposing an operation flag signal after the packet enable signal; And
And disposing an RF data timestamp signal after the operation flag signal.
The method of claim 7, wherein
In the step of disposing the packet enable signal, the packet enable signal is selected from any one of 41 ~ 255 Internet protocol packet generation method for remote monitoring and control of the RF signal of the femtocell device.
The method of claim 7, wherein
In the disposing of the operation flag signal, the operation flag signal selects one of an RF data start timestamp transmission signal and an RF data end timestamp transmission signal, and remotely monitor and control the RF signal of the femtocell device. Internet Protocol Packet Generation Method
9. The method of claim 8,
And disposing a packet enable acknowledgment signal between the packet enable signal and the operation flag signal after disposing the packet enable signal. Internet protocol packet generation method for a.
The method of claim 10,
In the disposing of the packet enable acknowledgment signal, the packet enable acknowledgment signal selects any one of 1 to 255. The method for generating an internet protocol packet for remote monitoring and controlling RF signals of a femtocell device.

Images