KR20050061835A - Gps antenna interface apparatus for mobile communication device - Google Patents

Abstract

The present invention relates to a GPS antenna interface device of a mobile communication terminal that enables external and internal GPS antennas to be commonly used in a mobile communication terminal. The present invention relates to an integrated type using a multi-band antenna for receiving a CDMA signal and a GPS signal together. A separate type mobile communication terminal having a mobile communication terminal and each antenna separately, comprising: a GPS RF connector for connecting an external GPS antenna; And a first and second RF switch for switching the GPS signal received through the built-in GPS antenna (gpsOne signal) and the GPS signal received through the GPS RF connector (Autonomous GPS signal) into two RF paths. In an integrated mobile communication terminal using a multi-band antenna for receiving a CDMA signal and a GPS signal together, and a separate mobile communication terminal in which each antenna is separately installed, when the external GPS antenna is connected, the existing connection is disconnected, and the external GPS antenna and A GPS RF mobile switch for connecting a GPS receiver block; It further includes an RF switch (SPDT RF Switch) for switching the GPS signal received via the built-in GPS antenna (gpsOne signal) or the GPS signal received via the GPS RF mobile switch (Autonomous GPS signal) to two RF paths; It can achieve by constructing.

Description

GPS antenna interface device of mobile communication terminal {GPS ANTENNA INTERFACE APPARATUS FOR MOBILE COMMUNICATION DEVICE}

The present invention relates to a GPS antenna interface device of a mobile communication terminal, and more particularly, to a GPS antenna interface device of a mobile communication terminal, which enables an external and a built-in global positioning system (GPS) antenna to be commonly used in a mobile communication terminal. .

In general, the Global Positioning System (GPS) is a satellite and ground control / monitoring system launched by the US Department of Defense for positioning using satellite signals and covers the entire world with 24 satellites.

Among them, gpsOne is a technology developed by Qualcomm, USA. It uses GPS satellite signals to perform location tracking. It receives GPS satellite information from mobile communication network in advance and tracks GPS satellite signals. It can shorten the time taken and increase the reception sensitivity.

The GPS (Global Positioning System) satellite is a low-orbiting satellite located at 20,000 km. It is not a geostationary satellite and has an orbital period of about 12 hours. Originally for military use, commercial use of some bands is now permitted. Each GPS satellite spreads 50bps navigation data containing its discrimination signal, location, signal integrity, and ionospheric information related to the radio wave environment to the 1.023Mhz P / N code and broadcasts it to the ground at 1575.42Mhz center frequency for 24 hours. have.

The GPS control station and the monitoring station operate the GPS satellites and update the satellite signals by uploading the latest data to the satellites. There are five Monitor Stations and one Master Control Station all over the world.

Next, an autonomous GPS receiver receives signals broadcast by GPS satellites, calculates pseudo-ranges of the satellites and receiver antennas from the satellite signal reception results, and calculates three or more pseudoranges. The position of the receiver antenna is calculated according to the principle of triangulation. The calculated coordinate is the ECEF coordinate system, which is converted to WGS84 coordinate system, which is the global coordinate system used in GPS, and then converted to Catek or TM coordinate system used in Korea and retrieved as map data. It works and does not need another mobile network.

In the Qualcomm's gpsOne method, Position Determination Equipment (PDE) is a server connected to a mobile communication network, and provides GPS satellite information requested by the gpsOne mobile communication terminal through the network, and the GPS satellite signal measured by the gpsOne terminal transmits the terminal. The location is calculated and returned to the terminal.

Next, the gpsOne-type mobile communication terminal adds a GPS path inside the RF, IF, and MSM configured for CDMA mobile communication, thereby minimizing additional parts to enable location tracking using a GPS satellite signal in the CDMA terminal. It was. In Korea, SK Telecom is offering a location tracking service by selling a CDMA terminal equipped with gpsOne function.

The location tracking method using the independent GPS receiver covers the entire world and is not charged separately for receiving GPS satellite signals, and can be used anywhere in the area where satellite signals are received, and the measured location information is transmitted to the user every second. Qualcomm gpsOne method enables location tracking function to be implemented in CDMA mobile communication terminal with minimum additional parts and time required for location tracking because GPS satellite information is transmitted from CDMA network through data communication. This has a shortened feature.

However, the location tracking method using an independent GPS receiver has to receive a lot of time of at least 30 seconds to measure the location because the 1500bit data transmitted from 50 or more satellites must be received from 3 or more satellites, and the Qualcomm gpsOne method uses GPS and CDMA. It uses two bands alternately instead of simultaneously, and it needs to transmit / receive data with the network positioning device (PDE), so it takes about 6 to 30 seconds for one position measurement. There is a problem of not providing a location within every second.

Accordingly, the present invention has been made to solve the above-mentioned problems, and the GPS antenna interface of the mobile communication terminal for improving the GPS reception performance by allowing external and internal GPS antennas to be commonly used in the mobile communication terminal. The object is to provide a device.

In order to achieve the above object, the present invention provides an integrated mobile communication terminal using a multi-band antenna for receiving a CDMA signal and a GPS signal together, and a separate mobile communication terminal in which each antenna is separately installed. GPS RF connector for; And a first and second RF switch for switching the GPS signal (gpsOne signal) received through the built-in GPS antenna and the GPS signal (Autonomous GPS signal) received through the GPS RF connector to two RF paths. It features.

In addition, the present invention is an integrated mobile communication terminal using a multi-band antenna for receiving a CDMA signal and a GPS signal together and a separate mobile communication terminal having each antenna separately, disconnecting the existing connection when the external GPS antenna is fastened, A GPS RF mobile switch for connecting an external GPS antenna and a GPS receiver block; It further includes an RF switch (SPDT RF Switch) for switching the GPS signal received via the built-in GPS antenna (gpsOne signal) or the GPS signal received via the GPS RF mobile switch (Autonomous GPS signal) to two RF paths; It is characterized by the configuration.

The present invention allows an external and internal GPS antenna to be used in common in a mobile communication terminal, and implements both GPS methods (gpsOne and Autonomous GPS) in the mobile communication terminal, thereby improving the GPS reception performance. It is aimed at the provision of.

Currently, mobile communication terminals capable of receiving GPS signals include an integrated mobile communication terminal configured using a GPS / CDMA multi-band antenna and a separate mobile communication terminal configured by separating a GPS antenna and a CDMA antenna. An object of the present invention is to provide an apparatus using a high frequency (RF) reception block in common by mounting an external GPS antenna on the integrated and detachable mobile communication terminals.

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

1 and 2 are block diagrams showing the configuration of an interface device using a common external GPS antenna in an integrated mobile communication terminal. First, FIG. 1 is a CDMA signal and a GPS signal received by a multi-band antenna 103. In an integrated mobile communication terminal comprising a diplexer 104 for separating (gpsOne signal), a low noise amplifier 105 for amplifying and filtering the separated GPS signal, and a GPS high frequency filter 113, an external GPS antenna GPS RF connector 111 for connecting the 101, GPS signal filtered through the GPS high frequency filter 113 (gpsOne signal) and GPS signal received via the GPS RF connector 111 (Autonomous GPS signal) It further comprises a first, second RF switch (SPDT RF Switch) 108a, 108b for switching to two RF paths.

In this case, the CDMA signal separated through the diplexer 104 is connected to the CDMA duplexer input terminal 114, and the GPS signals separated through the first and second switches 108a and 108b are independent GPS RF signal input terminals, respectively. 109 and gpsOne RF signal input 110.

2 shows a diplexer 104 for separating the CDMA signal and the GPS signal (gpsOne signal) received by the multi-band antenna 103, and a low noise amplifier 105 for amplifying and filtering the separated GPS signal. In the integrated mobile communication terminal consisting of the GPS high frequency filter 113, GPS RF mobile switch 106 for disconnecting the existing connection when the external GPS antenna 101 is fastened, and connecting the external GPS antenna and the GPS receiver block And an RF switch (SPDT) for switching a GPS signal (gpsOne signal) filtered through the GPS high frequency filter 113 or a GPS signal (Autonomous GPS signal) received through the GPS RF mobile switch 106 to two RF paths. RF switch) 108 further comprises.

As shown in FIG. 1, the CDMA signal separated through the diplexer 104 is connected to the CDMA duplexer input 114, and the GPS signals separated through the RF switch 108 are respectively independent GPS RF signal input 109. Or gpsOne RF signal input 110.

Next, FIG. 3 and FIG. 4 are block diagrams showing the configuration of an interface device using a common external GPS antenna in a separate mobile communication terminal. First, FIG. 3 is a diagram illustrating a separation of the CDMA antenna 112 and the built-in GPS antenna 102. In the detachable mobile communication terminal comprising a low noise amplifier 105 and a GPS high frequency filter 113 for amplifying and filtering a GPS signal (gpsOne signal) received through the built-in GPS antenna 102, the external GPS antenna 101 is provided. The GPS RF connector 111 for connecting the two signals, the GPS signal (gpsOne signal) filtered through the GPS high frequency filter 113 and the GPS signal (Autonomous GPS signal) received through the GPS RF connector 111 It further comprises a first, second RF switch (SPDT RF Switch) (108a, 108b) for switching to the RF path.

In this case, the signal received through the CDMA antenna 112 is connected to the CDMA duplexer input terminal 114, and the GPS signals separated through the first and second switches 108a and 108b are respectively independent GPS RF signal input terminals 109. ) And gpsOne RF signal input 110. For reference, the CDMA signal receiving path may include a CDMA RF mobile switch 107 for fastening an external CDMA antenna.

4 shows a low noise amplifier 105 and a GPS high frequency filter separating the CDMA antenna 112 and the built-in GPS antenna 102 and amplifying and filtering the GPS signal (gpsOne signal) received through the built-in GPS antenna 102. In the detachable mobile communication terminal consisting of 113, a GPS RF mobile switch 106 for disconnecting the existing connection when the external GPS antenna 101 is fastened and connecting the external GPS antenna and the GPS receiver block, and the GPS high frequency SPDT RF Switch 108 for switching the GPS signal filtered through the filter 113 (gpsOne signal) or the GPS signal received via the GPS RF mobile switch 106 (Autonomous GPS signal) to two RF paths. ) Is further included.

In this case, the signal received through the CDMA antenna 112 is connected to the CDMA duplexer input terminal 114, and the GPS signals separated through the first and second switches 108a and 108b are respectively independent GPS RF signal input terminals 109. ) And gpsOne RF signal input 110.

1 and 3 require two SPDT RF switches to control two GPIO ports on the MSM side, and 2 and 4 control one SPDT RF switch to require one GPIO port on the MSM side. Do. In all cases, GPIO1 determines the type of receiving antenna and GPIO2 determines whether the receiving mode is Qualcomm gpsOne or standalone GPS.

The external GPS antenna 101 is an antenna that exists separately outside the terminal, and is an antenna component that integrates a patch antenna having a high directivity and a relatively large volume, a GPS low noise amplifier (LNA), and a GPS RF filter. The signal is fed through the LNA to the GPS receiver via the RF cable to compensate for the path loss of the RF cable.

Next, the built-in GPS antenna 102 has a smaller volume than the patch antenna, but the reception performance is lowered and is not seen from the outside because it is surrounded by the terminal case, and the pedestrian navigation degree is relatively lower than the patch type antenna when used outdoors. It can be used in vehicles or indoors in some cases, but when the reception performance is insufficient, it is supplemented by using an external GPS antenna.

Next, the GPS / CDMA multiband antenna 103 is an antenna component capable of receiving all signals of various frequency bands such as DCN, PCS, GPS, etc., and is used to save component mounting space of a mobile communication terminal and reduce component prices. do. Compared with the built-in GPS antenna, the GPS signal is received from the head of the terminal outside the terminal case, so the signal receiving environment is relatively superior. However, RF matching is required for the various bands, and the electromagnetic wave absorption and reception sensitivity are relatively difficult. There is a characteristic.

Next, the GPS / CDMA diplexer 104 is a passive component used to divide the GPS / CDMA signal into two paths when using a multi-band antenna, and also provides isolation between each frequency band, and the GPS LNA 105. Is located as close to the GPS antenna as possible to compensate for the path loss.

Next, the GPS RF mobile switch 106 is located between the built-in GPS antenna and the GPS receiver block, and normally connects two blocks, and when the external GPS antenna is connected, disconnects the existing connection and connects the external GPS antenna and the GPS receiver block. In this way, each time the user tightens the connector, it is mechanically operated.

As described above, the GPS antenna interface device of the mobile communication terminal of the present invention has an effect of improving the GPS reception performance by allowing external and internal GPS antennas to be commonly used in the mobile communication terminal.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing a configuration of a first embodiment of an interface device which uses an external GPS antenna in common in an integrated mobile communication terminal.

2 is a block diagram showing a configuration of a second embodiment of an interface device which uses an external GPS antenna in common in an integrated mobile communication terminal.

3 is a block diagram showing a configuration of a first embodiment of an interface device which uses an external GPS antenna in common in a detachable mobile communication terminal;

Figure 4 is a block diagram showing the configuration of a second embodiment of an interface device which uses an external GPS antenna in common in a detachable mobile communication terminal.

* Description of the symbols for the main parts of the drawings *

101: external GPS antenna 102: internal GPS antenna

103: multi-band antenna 104: diplexer

105: low noise amplifier 106: GPS RF mobile switch

107CDMA RF Mobile Switch 108108a108b RF Switch

109: standalone GPS RF signal input terminal 110: gpsOne RF signal input terminal

111: GPS RF connector 112: CDMA antenna

113: GPS RF filter 114: CDMA duplexer input

Claims (3)

In the integrated mobile communication terminal using a multi-band antenna for receiving a CDMA signal and a GPS signal together, and a separate mobile communication terminal with each antenna separately, A GPS RF connector for connecting an external GPS antenna; And a first and second RF switch for switching the GPS signal (gpsOne signal) received through the built-in GPS antenna and the GPS signal (Autonomous GPS signal) received through the GPS RF connector to two RF paths. GPS antenna interface device of a mobile communication terminal. The GPS antenna interface apparatus of claim 1, wherein the first and second RF switches are configured to select a type and a reception mode of a reception antenna through a GPIO port of a terminal control unit (MSM). In the integrated mobile communication terminal using a multi-band antenna for receiving a CDMA signal and a GPS signal together, and a separate mobile communication terminal with each antenna separately, A GPS RF mobile switch for disconnecting the existing connection when the external GPS antenna is fastened and connecting the external GPS antenna to the GPS receiver block; It further includes an RF switch (SPDT RF Switch) for switching the GPS signal received via the built-in GPS antenna (gpsOne signal) or the GPS signal received via the GPS RF mobile switch (Autonomous GPS signal) to two RF paths; GPS antenna interface device of a mobile communication terminal, characterized in that configured.