KR20050065791A - Receiver for base station - Google Patents

Abstract

The present invention relates to a base station receiving apparatus including a base station channel card for demodulating all the signals in a DWL, and including: a signal divider for splitting a TMD delayed optical signal and an RFMC signal in multiple directions received through a base station antenna; And a delay that causes a time delay in the RFMC signal and a time delayed delayed optical signal and a non-time delayed original RFMC signal to have a time difference within the DWL, and an original signal divided and bypassed by the time delayed delay signal and the signal divider. And a base station channel card for combining and demodulating all of the delayed optical signal and the original RFMC signal in the DWL among the transmitted delay signal and the original signal, and the time difference between the optical signal and the RFMC signal in the base station channel card All signals can be demodulated even beyond the DWL that can be handled, resulting in There is a possible benefit.

Description

Base station receiver {RECEIVER FOR BASE STATION}

The present invention relates to a base station receiver, and more particularly, to demodulate even when a time difference between a received optical signal and a Radio Fiber Optic Micro Cell (RFMC) signal exceeds a Demodulation Window Length (DWL) that can be processed by a base station channel card. One base station receiver.

As is well known, base stations of a code division multiple access (CDMA) system are classified into a CSM base station employing a Cell Site Manager (CSM) channel card and a BSM base station employing a Base Station Manager (BSM) channel card.

The channel card modulates a voice signal at the terminal and transmits a modulated signal to demodulate the received signal from the modem of the base station. The channel card is a card containing the modem. The difference between the CSM channel card and the BSM channel card is to demodulate the signal. DWL is different.

In detail, when a terminal transmits a modulated signal to a base station, the signal enters various paths according to a radio wave environment such as a feature or a building. That is, if a terminal does not transmit one signal, the signal path is changed and the base station side is changed. Will receive multiple signals with time differences.

At this time, since the base station is a signal sent from one terminal, the signal strength is increased and beneficial in many ways to collect all signals received with a time difference. For example, if a signal is received with parallax with three paths, it is best to combine all three signals into a single signal. The channel card has the time to wait for the next signal after receiving the first signal (DWL). If the second signal is received after receiving the first signal and not beyond DWL, then both the first and second signals are demodulated, but if the second signal is received beyond DWL after receiving the first signal, the second signal is demodulated. It is not used to.

DWL of CSM channel card is smaller than DWL of BSM channel card. In general, CSM channel card can't demodulate signal of base station and optical repeater at modem when optical distance is over 2.5km. In case of BSM channel card, Up to about 10km is possible.

On the other hand, the CSM base station employing the CSM channel card will be described whether the RFMC can be installed more than 3km wide. RFMC is a kind of optical repeater. In general, optical repeater installs donor in base station, but RFMC installs donor away from base station and receives input signal by RF and sends it remotely.

1 is a block diagram of a CMS base station in which an RFMC is installed, and includes a mother station 11, a TMD (Time Matching Device) 12, an optical repeater 13, an RFMC donor 14, and an RFMC remote 15. It is composed.

The TMD 12 is a device that randomly delays the signal and is adopted because of the DWL limitation of the CSM channel card modem. For example, if the CWL channel card modem has a DWL of 3 seconds and a signal from the other paths of A and B enters with a 5 second time delay, the modem of the channel card cannot add and demodulate both signals simultaneously. Therefore, the first A signal generates a time delay in the TMD 12. For example, if the delay of 3 seconds is delayed, the modem of the CSM channel card can demodulate the sum of the two signals because the time delay between the A signal and the B signal is only 2 seconds. It is.

The RFMC donor 14 receives the RF signal from the base station, converts the optical signal into an optical signal, and sends the optical signal to the RFMC remote 15 through the optical path. The RFMC remote 15 converts the received optical signal into an RF signal and transmits the amplified signal.

Referring to FIG. 2, a signal transmission process based on a TMD delay in a CMS base station configured as described above is performed by the optical repeater 13 because the first optical signal is delayed by the TMD 12. Since both signals can be demodulated, handoff between the main station 11 and the optical repeater 13 is possible.

However, there is a problem that the handoff between the optical repeater 13 and the RFMC donor 14 cannot be demodulated since the next RFMC signal is also delayed by the TMD chip delay, so that both signals cannot be demodulated.

The present invention has been proposed to solve such a conventional problem, and provides a base station receiver capable of demodulating all signals even when the time difference between the received optical signal and the RFMC signal exceeds a DWL that can be processed by the base station channel card. The purpose is.

The present invention for realizing the above object is a base station receiving apparatus including a base station channel card for demodulating all the sum of the signals in the DWL, the signal received by the base station antenna to divide the TMD delayed optical signal and RFMC signal in multiple directions A retarder for causing a time delay between the period, the optical signal divided by the signal divider and the RFMC signal, and causing the time-delayed delayed optical signal and the non-time-delayed original RFMC signal to have a time difference in the DWL; A signal combiner for combining a time-delayed delay signal and an original signal divided by the signal divider and bypassed; the delayed optical signal and the original RFMC in the DWL among the delayed signal and the original signal transmitted through the signal combiner; And a base station channel card that sums and demodulates all the signals.

There may be a plurality of embodiments of the present invention. Hereinafter, preferred embodiments will be described in detail with reference to the accompanying drawings. This embodiment allows for a better understanding of the objects, features and advantages of the present invention.

As shown in the block diagram of FIG. 3, the base station receiver according to the present invention includes a bandpass filter 101, a low noise amplifier 102, a TMD 103, a signal divider 104, a delayer 105, And a signal combiner 106, an amplifier 107, and a base station channel card 108.

The bandpass filter 101 passes only a predetermined signal band among the signals received from the base station antenna, and the low noise amplifier 102 amplifies the weak received signal and transmits it to the TMD 103.

The TMD 103 is a device that randomly delays the signal and is adopted due to the DWL limitation of the channel card modem as described in the prior art.

The signal divider 104 divides the optical signal and the RFMC signal which are delayed and transmitted by the TMD 103 in a plurality of directions, and the retarder 105 is used to divide the optical signal and the optical signal divided to one side by the signal divider 104. Inducing a time delay in the RFMC signal, the signal combiner 106 combines the signal divided on the other side by the signal divider 104 and the time delayed by the delay unit 105.

The output signal of the signal combiner 106 is amplified by the amplifier 107 and delivered to the base station channel card 108, where the modem of the base station channel card 108 sums and demodulates the signals in the DWL.

Looking at the signal transmission process by the base station receiving apparatus according to the present invention configured as described above with reference to Figure 4, the signal received through the base station antenna is filtered through the band pass filter 101 only the reception band signal of the service provider, The filtered weak signal is amplified via the low noise amplifier 102.

When the TMD delayed signal is transmitted to the signal divider 104 through the TMD 103, the signal is divided in two directions so that the divided signal in one direction is input to the delay unit 105, and the signal divided in the other direction is The signal is bypassed without passing through the delay unit 105 and input to the signal combiner 106.

The delay unit 105 induces a predetermined time delay in the signal divided in one direction by the signal divider 104 and transmits it to the signal combiner 106.

Referring to FIG. 4, the optical signal divided by the signal divider 104 and the RFMC signal, that is, the original signal have a time difference outside the DWL range that can be demodulated by the base station channel card 108 by a TMD delay. The signal passed by the signal to the signal combiner 106 after being dispensed by the 104 without passing through the delay unit 105 is the same as the original signal.

Then, the signal divided by the signal divider 104 and passed through the delay unit 105 to the signal combiner 106, like the original signal, is outside the range of the DWL that can be demodulated in the base station channel card 108 by the TMD delay as in the original signal. The signal is transmitted to the signal combiner 106 in a state where there is a time difference but a predetermined time delay occurs.

Here, the signal combiner 106 combines the original signal bypassed via the signal divider 104 and the delayed signal delayed by the delayer 105, and the optical signal delayed by the delayer 105 The passed RFMC signal has a time difference in the DWL that can be demodulated in the base station channel card 108.

As such, the combined signal of the original signal and the delayed signal is amplified by the amplifier 107 by the signal combiner 106 and then transferred to the base station channel card 108, and the base station channel card 108 adjusts the time difference in the demodulated DWL. The optical signal and the RFMC signal, ie, the optical signal delayed by the delay unit 105 and the bypassed RFMC signal are summed and demodulated.

In the above description, but limited to one embodiment of the present invention, it is obvious that the technology of the present invention can be easily modified by those skilled in the art. Such modified embodiments should be included in the technical spirit described in the claims of the present invention.

As described above, the present invention can demodulate all signals even when the time difference between the optical signal and the RFMC signal exceeds the DWL that can be processed by the base station channel card, thereby enabling the handoff between the optical repeater and the RFMC.

1 is a block diagram of a CMS base station with RFMC installed according to the prior art;

FIG. 2 is a diagram comparing a pseudo noise phase (PN_Phase) before and after installing a TMD in a base station shown in FIG. 1;

3 is a block diagram of a base station receiving apparatus according to the present invention;

FIG. 4 is a view illustrating a change in pseudonoise phase due to division and combining in the base station shown in FIG.

Claims (1)

A base station receiving apparatus including a base station channel card that demodulates all the sum of signals in a demodulation window length (DWL), A signal divider for splitting a TMD (Time Matching Device) delayed optical signal and a Radio Fiber Optic Micro Cell (RFMC) signal in multiple directions through a base station antenna; A retarder causing a time delay between the optical signal and the RFMC signal divided by the signal divider to cause a time delayed delayed optical signal and a time delayed original RFMC signal to have a time difference within the DWL; A signal combiner for combining the delayed signal delayed by the delayer and the original signal divided and bypassed by the signal divider; The base station channel card which demodulates all of the delayed optical signal and the original RFMC signal in the DWL among the delayed signal and the original signal transmitted through the signal combiner; Base station receiving apparatus comprising a.