CN100407596C - Apparatus capable of constituting multi-mobile communication equipment and constituted mobile communication equipment thereof - Google Patents

Abstract

The present invention discloses a device capable of forming multiple mobile communication equipment, which comprises a front end module and a user side module, wherein the front end module and the user side module can be connected mutually, and various mobile communication equipment, such as a radio frequency repeater station, a far end of an optical fiber repeater station, a radio frequency remote device, a micro base station, etc. can be formed flexibly and conveniently in modular method. Because the device uses digital transmission technique, and interfaces are uniform, the module generalization degree of the radio frequency repeater station, the far end of the optical fiber repeater station, the radio frequency remote device and the micro base station is enhanced greatly, and the cost for building and upgrading a network is reduced for an operator. Meanwhile, the present invention also discloses a plurality of the radio frequency repeater stations, the far ends of the optical fiber repeater stations, the radio frequency remote devices and the micro base stations composed of the device. Part of same modules can be shared by the mobile communication equipment, so the present invention is favorable for upgrading the equipment; not only the problem of network optimization is solved, but also great flexibility of network construction is provided.

Description

Can constitute the device of multiple mobile communication equipment and the mobile communication equipment of formation thereof

Technical field

The present invention relates to mobile communication technology, particularly relate to a kind of repeater, little base station and radio frequency remote equipment.

Background technology

Repeater (repeater) is meant a kind of radio transmission transferring equipment that plays the enhancing signal effect in the wireless communication transmissions process, and the typical case of repeater uses the blind area covering that mainly comprises system, suburb covering, the covering along the line of highway, indoor covering etc.The basic function of repeater is exactly a radiofrequency signal power intensifier.The repeater by donor antenna pickoff signals from existing overlay area, isolates the signal beyond the passband by band pass filter in down link, the signal of filtering is transmitted into after power amplifier amplifies once more treats the overlay area; In the uplink path, forwarding antenna receives the signal of the travelling carriage in the overlay area, by band pass filter signal is handled, the signal with filtering is transmitted into corresponding base station after power amplifier amplifies then, thereby reaches the signal transmission of base station and travelling carriage.

The type of existing repeater has optical fiber repeater, RF direct amplifying station and microwave relay repeater etc.Wherein RF direct amplifying station and optical fiber repeater are modal two kinds of repeaters.Be example with the RF direct amplifying station below, briefly introduce the structure and the operation principle of existing repeater:

Fig. 1 is the structure chart of existing RF direct amplifying station, and its operation principle is as follows: at down direction, receive that by donor antenna the downstream signal of base station delivers to power amplifier and amplify, launched by forwarding antenna; At up direction, receive that by forwarding antenna the upward signal of base station is finished simulation frequency conversion work after low noise amplifier amplifies in frequency range selector, the upward signal after filter filtering is with frequency conversion is delivered to power amplifier and is amplified, and is launched by donor antenna.Whole process all is to finish in analog circuit.

Existing RF direct amplifying station is generally integral structure, can't with optical fiber repeater far-end common parts, also can't be smoothly transitted into base station and radio frequency remote equipment according to user's needs.And because RF direct amplifying station generally uses analogue device to realize, consistency is poor in batches, can't large-scale production.

Fig. 2 is the structure chart of existing optical fiber repeater, mainly is made up of near-end machine, optical fiber, remote termination several sections.Its operation principle is as follows: at down direction, after wireless signal is coupled out from the base station, enter the near-end machine, by the electric light conversion, the signal of telecommunication changes light signal into, input to optical fiber from the near-end machine, to remote termination, remote termination transfers light signal to the signal of telecommunication, and amplification signal through Optical Fiber Transmission, the signal of telecommunication is sent into transmitting antenna, the coverage goal zone after amplifying; At up direction, after the signal of travelling carriage emission is received, enter remote termination, remote termination transfers the signal of telecommunication to light signal, to the near-end machine, again by opto-electronic conversion, transfers signal to the signal of telecommunication at the near-end machine through Optical Fiber Transmission, sends into the base station through after amplifying.

In order to reduce the cost of optical fiber repeater, what most of producers used is the analogue transmission technology, general Optical Receivers and the light emission module that uses high power laser reflector and laser receiver to constitute, in use need to adjust the power of generating laser, to overcome the influence of fibre loss to transmitting power.Thereby most of modules of optical fiber repeater far-end and RF direct amplifying station can't be shared, also can't be smoothly transitted into little base station and radio frequency remote equipment.

In existing mobile communications system, in order to solve covering problem, the repeater is adopted in a large number, and according to the CDMA real application data, the ratio of base station and repeater was near 1: 10, and therefore, the number of the repeater in the network is very many.But from now on along with the continuous increase of number of users, channel resource will become new contradiction, because the repeater does not have the function of dilatation, so the repeater can not satisfy the needs that channel demands increases day by day, and should be replaced by little base station and radio frequency remote equipment with dilatation function.

The principle of little base station is as follows: at down direction, the optical fiber that Radio Link Controller is transmitted in little base station (or E1) conversion of signals becomes original downstream signal, and to downstream signal encode, multiplexing, spread spectrum, scrambling and framing handle, form a downgoing baseband signal, finish the conversion of intermediate-freuqncy signal then, and downstream signal is launched by power amplifier to radiofrequency signal; At up direction, the upward signal of sending from aerial receiving mobile, this radiofrequency signal is converted to intermediate-freuqncy signal, intermediate-freuqncy signal is converted to digital baseband signal through rate adapted, shunt processing, power adjustment, again this digital baseband signal is carried out demodulation, decoding processing, form Frame Protocol (FP) packet format,, be sent to Radio Link Controller by optical fiber through framing and opto-electronic conversion.

Radio frequency remote equipment can be moved the coverage of base station to other place, thereby increases coverage.If be used for dilatation, can adopt the base station that number of users is less to tell a radio frequency remote equipment and absorb the user, thereby reach the purpose of dilatation to the many hot zones of user.

The principle of radio frequency remote equipment is as follows, at down direction, the light signal that the base station is transmitted reverts to the signal of telecommunication, isolate baseband signal and control signal, processes such as carrying out power control, close the road, data are adaptive, and convert digital signal to intermediate-freuqncy signal, convert intermediate-freuqncy signal to radiofrequency signal then, and downstream signal is launched by power amplifier; At up direction, the upward signal of sending from aerial receiving mobile, convert radiofrequency signal to intermediate-freuqncy signal, be converted to digital baseband signal through rate adapted, shunt processing, power adjustment again, the control answer signal is mixed framing with up baseband signal, convert light signal to and pass the base station back.

A kind of mode of network operation cheaply need be sought by operator, but because the upgradability and the extendible capacity of existing repeater are relatively poor, so the dilatation of a lot of repeaters all is that former repeater is removed, operator purchases new little base station or radio frequency remote equipment more again, has so just wasted operation cost greatly.

In order to realize the low-cost network operation mode of repeater, need the shared a plurality of modules of RF direct amplifying station, optical fiber repeater and little base station or radio frequency remote equipment, with the stock equipment quantity of reduction operator, thus the cost of minimizing operator networking.

Summary of the invention

The object of the present invention is to provide RF direct amplifying station, optical fiber repeater far-end, little base station and radio frequency remote equipment, these equipment constitute by the front-end module and the user side module of the device that can constitute multiple mobile communication equipment, can RF direct amplifying station, optical fiber repeater far-end, little base station and radio frequency remote equipment be replaced by miscellaneous equipment by the method that module is replaced.

The objective of the invention is to be achieved through the following technical solutions:

A kind of mobile communication equipment, described mobile communication equipment are RF direct amplifying station,

Described RF direct amplifying station comprises:

Front-end module, be used to receive the downlink radio-frequency signal of holding antenna from the alms giver, be sent to the user side module after described downlink radio-frequency signal is converted to descending intermediate-freuqncy signal, and receive up intermediate-freuqncy signal from the user side module, described up intermediate-freuqncy signal is converted to is sent to the alms giver after the up radiofrequency signal and holds antenna;

The user side module, be used to receive up radiofrequency signal from the user side antenna, be sent to front-end module after described up radiofrequency signal is converted to up intermediate-freuqncy signal, and receive descending intermediate-freuqncy signal from front-end module, after being converted to downlink radio-frequency signal, described descending intermediate-freuqncy signal is sent to the user side antenna;

Wherein, front-end module comprises:

Front-end module control channel, being used for forward end module by signal treatment channel sends control information, reception is from the state information of front-end module signal processing channel, reception is from the reference clock of front-end module clock passage, by standard digital interface and user side module control unit transmitting control information;

The front-end module signal processing channel, be used for forward end module controls passage send state information, reception is from the control information of front-end module control channel, reception is from the reference clock of front-end module clock passage, the downlink radio-frequency signal of antenna is held in reception from the alms giver, be sent to user side module radio-frequency channel after described downlink radio-frequency signal is converted to descending intermediate-freuqncy signal, reception is from the up intermediate-freuqncy signal of user side module radio-frequency channel, described up intermediate-freuqncy signal is converted to be sent to the alms giver after the up radiofrequency signal and hold antenna; And

Front-end module clock passage is used to produce the required reference clock of front-end module, and forward end module controls passage and front-end module signal processing channel send reference clock,

The user side module comprises:

The user side module control unit, be used for sending control information to user side module radio-frequency channel, reception receives the reference clock from user side module clock unit, by standard digital interface and front-end module control channel transmitting control information from the state information of user side module radio-frequency channel;

User side module radio-frequency channel, be used for to user side module control unit send state information, reception is from the control information of user side module control unit, reception is from the reference clock of user side module clock unit, by the descending intermediate-freuqncy signal of standard analog interface reception from the front-end module signal processing channel, be sent to the user side antenna after described descending intermediate-freuqncy signal is converted to downlink radio-frequency signal, reception is from the up radiofrequency signal of user side antenna, is sent to the front-end module signal processing channel by the standard analog interface after described up radiofrequency signal is converted to up intermediate-freuqncy signal; And

User side module clock unit, being used for the clock reference signal from front-end module clock passage that receives is that benchmark produces the required reference clock of user side module, sends reference clock to user side module control unit and user side module radio-frequency channel.

A kind of mobile communication equipment, described mobile communication equipment are the optical fiber repeater far-end,

The optical fiber repeater far-end comprises:

Front-end module, be used to receive descending digital signal from the optical fiber repeater far-end of optical fiber repeater near-end or upper level cascade, be sent to the user side module after described descending digital signal is converted to descending intermediate-freuqncy signal, or the digital uplink signal of the optical fiber repeater far-end of reception next stage cascade, and with described digital uplink signal and the optical fiber repeater far-end of delivering to optical fiber repeater near-end or upper level cascade from the up intermediate-freuqncy signal hybrid concurrency of user side module;

The user side module, be used to receive descending intermediate-freuqncy signal from front-end module, be sent to the user side antenna after described descending intermediate-freuqncy signal is converted to downlink radio-frequency signal, with the up radiofrequency signal that receives from the user side antenna, be sent to front-end module after described up radiofrequency signal is converted to up intermediate-freuqncy signal;

Wherein, front-end module comprises:

Front-end module control channel, being used for forward end module by signal treatment channel sends control information, reception is from the state information of front-end module signal processing channel, reception is from the reference clock of front-end module clock passage, by standard digital interface and user side module control unit transmitting control information;

The front-end module signal processing channel, be used for forward end module controls passage send state information, reception is from the control information of front-end module control channel, reception is from the reference clock of front-end module clock passage, reception is from the descending digital signal of the optical fiber repeater far-end of optical fiber repeater near-end or upper level cascade, be sent to user side module radio-frequency channel after described descending digital signal is converted to descending intermediate-freuqncy signal, reception is from the up intermediate-freuqncy signal of user side module radio-frequency channel, with described up intermediate-freuqncy signal conversion digital uplink signal, and be treated to the optical fiber repeater far-end that is sent to optical fiber repeater near-end or upper level cascade behind the required signal of the optical fiber repeater far-end of optical fiber repeater near-end or upper level cascade; And

Front-end module clock passage is used to produce the required reference clock of front-end module, and forward end module controls passage and front-end module signal processing channel send reference clock,

The user side module comprises:

The user side module control unit, be used for sending control information to user side module radio-frequency channel, reception receives the reference clock from user side module clock unit, by standard digital interface and front-end module control channel transmitting control information from the state information of user side module radio-frequency channel;

User side module radio-frequency channel, be used for to user side module control unit send state information, reception is from the control information of user side module control unit, reception is from the reference clock of user side module clock unit, by the descending intermediate-freuqncy signal of standard analog interface reception from the front-end module signal processing channel, be sent to the user side antenna after described descending intermediate-freuqncy signal is converted to downlink radio-frequency signal, reception is from the up radiofrequency signal of user side antenna, is sent to the front-end module signal processing channel by the standard analog interface after described up radiofrequency signal is converted to up intermediate-freuqncy signal; And

User side module clock unit, being used for the clock reference signal from front-end module clock passage that receives is that benchmark produces the required reference clock of user side module, sends reference clock to user side module control unit and user side module radio-frequency channel.

A kind of mobile communication equipment, described mobile communication equipment are radio frequency remote equipment,

Radio frequency remote equipment comprises:

Front-end module, be used to receive descending digital signal from the radio frequency remote equipment of base station or upper level cascade, be sent to the intermediate frequency process module after described descending digital signal is converted to descending intermediate-freuqncy signal, or the digital uplink signal of the radio frequency remote equipment of reception next stage cascade, and with described digital uplink signal and the radio frequency remote equipment that send base station or upper level cascade from the up intermediate-freuqncy signal hybrid concurrency of user side module;

The user side module, be used to receive descending intermediate-freuqncy signal from front-end module, be sent to the user side antenna after described descending intermediate-freuqncy signal is converted to downlink radio-frequency signal, with the up radiofrequency signal that receives from the user side antenna, be sent to front-end module after described up radiofrequency signal is converted to up intermediate-freuqncy signal;

Wherein, front-end module comprises:

Front-end module control channel, being used for forward end module by signal treatment channel sends control information, reception is from the state information of front-end module signal processing channel, reception is from the reference clock of front-end module clock passage, by standard digital interface and user side module control unit transmitting control information;

The front-end module signal processing channel, be used for forward end module controls passage send state information, reception is from the control information of front-end module control channel, reception is from the reference clock of front-end module clock passage, reception is from the descending digital signal of the radio frequency remote equipment of base station or upper level cascade, be sent to user side module radio-frequency channel after described descending digital signal is converted to descending intermediate-freuqncy signal, reception is from the up intermediate-freuqncy signal of user side module radio-frequency channel, described up intermediate-freuqncy signal is converted to digital signal, and is treated to the radio frequency remote equipment that is sent to base station or upper level cascade behind the required signal of the radio frequency remote equipment of base station or upper level cascade; And

Front-end module clock passage is used to produce the required reference clock of front-end module, and forward end module controls passage and front-end module signal processing channel send reference clock,

The user side module comprises:

The user side module control unit, be used for sending control information to user side module radio-frequency channel, reception receives the reference clock from user side module clock unit, by standard digital interface and front-end module control channel transmitting control information from the state information of user side module radio-frequency channel;

User side module radio-frequency channel, be used for to user side module control unit send state information, reception is from the control information of user side module control unit, reception is from the reference clock of user side module clock unit, by the descending intermediate-freuqncy signal of standard analog interface reception from the front-end module signal processing channel, be sent to the user side antenna after described descending intermediate-freuqncy signal is converted to downlink radio-frequency signal, reception is from the up radiofrequency signal of user side antenna, is sent to the front-end module signal processing channel by the standard analog interface after described up radiofrequency signal is converted to up intermediate-freuqncy signal; And

User side module clock unit, being used for the clock reference signal from front-end module clock passage that receives is that benchmark produces the required reference clock of user side module, sends reference clock to user side module control unit and user side module radio-frequency channel.

A kind of mobile communication equipment, described mobile communication equipment are little base station,

Little base station comprises:

Front-end module, be used to receive descending digital signal from base station controller, described descending encoding digital signals, descending modulation treatment are formed baseband signal, and be sent to the user side module after being converted to descending analog intermediate frequency signal, with the up intermediate-freuqncy signal that receives from the user side module, described up intermediate-freuqncy signal is converted to digital signal, and carries out being sent to base station controller after uplink demodulation, the decoding processing;

The user side module, be used to receive up radiofrequency signal from the user side antenna, be sent to front-end module after described up radiofrequency signal is converted to up intermediate-freuqncy signal, with the descending analog baseband signal that receives from front-end module, be sent to the user side antenna after described descending analog intermediate frequency signal is converted to downlink radio-frequency signal;

Wherein, front-end module comprises:

Front-end module control channel, being used for forward end module by signal treatment channel sends control information, reception is from the state information of front-end module signal processing channel, reception is from the reference clock of front-end module clock passage, by standard digital interface and user side module control unit transmitting control information;

The front-end module signal processing channel, be used for forward end module controls passage send state information, reception is from the control information of front-end module control channel, reception is from the reference clock of front-end module clock passage, reception is from the descending digital signal of base station controller, be sent to user side module radio-frequency channel after described descending digital signal is converted to descending analog intermediate frequency signal, reception is from the up intermediate-freuqncy signal of user side module radio-frequency channel, described up intermediate-freuqncy signal is converted to digital signal, and is sent to base station controller after being treated to the required signal of base station controller; And

Front-end module clock passage is used to produce the required reference clock of front-end module, and forward end module controls passage and front-end module signal processing channel send reference clock,

The user side module comprises:

The user side module control unit, be used for sending control information to user side module radio-frequency channel, reception receives the reference clock from user side module clock unit, by standard digital interface and front-end module control channel transmitting control information from the state information of user side module radio-frequency channel;

User side module radio-frequency channel, be used for to user side module control unit send state information, reception is from the control information of user side module control unit, reception is from the reference clock of user side module clock unit, by the descending analog intermediate frequency signal of standard analog interface reception from the front-end module signal processing channel, be sent to the user side antenna after described descending analog intermediate frequency signal is converted to downlink radio-frequency signal, reception is from the up radiofrequency signal of user side antenna, is sent to the front-end module signal processing channel by the standard analog interface after described up radiofrequency signal is converted to up intermediate-freuqncy signal; And

User side module clock unit, being used for the clock reference signal from front-end module clock passage that receives is that benchmark produces the required reference clock of user side module, sends reference clock to user side module control unit and user side module radio-frequency channel.

The device that constitutes multiple mobile communication equipment according to the present invention can constitute multiple mobile communication equipments such as RF direct amplifying station, optical fiber repeater far-end, radio frequency remote equipment and little base station flexibly and easily in modular mode.Because the multiple mobile communication equipment that this device constitutes uses digital transmission technology, interface is unified, and publicization of the module degree of multiple mobile communication equipment is improved greatly, has reduced the networking and the upgrade cost of operator.Because this device adopts modularization and standardization, so concerning manufacturer, also can significantly reduce development cost.Simultaneously, this device has reduced the demand of networking initial stage to transfer resource, the repeater that can make things convenient for when the demand of transfer resource increases and will not have the dilatation ability smoothly upgrades to radio frequency remote equipment or the little base station with dilatation ability, not only solved the problem of the network optimization, also provide bigger flexibility to networking.

Description of drawings

Fig. 1 is the structural representation of existing RF direct amplifying station;

Fig. 2 is the structural representation of existing optical fiber repeater;

Fig. 3 is the structural representation that constitutes the device of multiple mobile communication equipment according to of the present invention;

Fig. 4 is the structural representation that constitutes RF direct amplifying station according to device of the present invention;

Fig. 5 is the structural representation that constitutes the optical fiber repeater far-end according to device of the present invention;

Fig. 6 is the structural representation that constitutes radio frequency remote equipment according to device of the present invention;

Fig. 7 is the structural representation that device according to the present invention constitutes little base station.

Embodiment

In order to make the purpose, technical solutions and advantages of the present invention clearer, the present invention is further described below in conjunction with the drawings and specific embodiments.

The description of this paper for convenience, be example now with Wideband Code Division Multiple Access (WCDMA) (WCDMA) standard, but the present invention not only is applied to WCDMA, also can be applied to a plurality of popular wireless standards in the world wide, comprise: global system for mobile communications (GSM) 900/1800/1900, time division multiple access (TDMA)/digital advanced mobile phone service (D-AMPS), code division multiple access (CDMA) and time division duplex-S-CDMA standards such as (TD-SCDMA).

The invention provides a kind of device that constitutes multiple mobile communication equipment, as shown in Figure 3, device 300 comprises user side module 320 and front-end module 310.

As can be seen from Figure 3, user side module 320 comprises control unit 321, radio-frequency channel 322 and clock unit 323.Control unit 321 comprises central processing unit and telecommunication unit, is used for sending control information to radio-frequency channel 322, and the state information sent of receiving RF channel 322; Radio-frequency channel 322 comprises low-converter on the radio frequency, divides mixer, power amplifier, filter and low noise amplifier, mainly finishes the radiofrequency signal in the user side module 320 and the transformation function of intermediate-freuqncy signal; Clock unit 323 comprises frequency synthesizer, and the clock reference of sending here with the clock passage 313 of front-end module 310 serves as with reference to producing the required reference clock of user side module 320.

User side module 320 control units 321 are connected with front-end module 310 control channels 311; User side module 320 clock units 323 are connected with front-end module 310 clock passages 313; The front of user side module 320 radio-frequency channels 322 is connected with front-end module 310 signal processing channels 312, and the antenna side of user side module 320 radio-frequency channels 322 is connected with the user side antenna.

Front-end module 310 comprises control channel 311, signal processing channel 312 and clock passage 313.The function of front-end module 320 is: at down direction, receive the signal come from headend equipment, and be sent to user side module 320 after this signal handled; At up direction: receive the signal that comes from user side module 320, and be sent to headend equipment after this signal handled.In addition, front-end module 310 also produces the required reference clock of this module each several part, and reference clock is sent to the clock unit 323 of user side module 320 by the clock interface of standard.

As can be seen from Figure 3, front-end module 310 control channels 311 are connected with user side module 320 control units 321; The user of front-end module 310 signal processing channels 312 is distolateral to be connected with user side module 320 radio-frequency channels 322, and the equipment side of front-end module 310 signal processing channels 312 is connected with headend equipment; Front-end module 310 clock passages 313 are connected with user side module 320 clock units 323.

More than be the device that constitutes multiple mobile communication equipment according to of the present invention, this device can constitute multiple mobile communication equipment, such as RF direct amplifying station, optical fiber repeater far-end, little base station and Remote Radio Unit or the like.

The multiple mobile communication equipment that the present invention also provides said apparatus to constitute is as RF direct amplifying station, optical fiber repeater far-end, radio frequency remote equipment and little base station.Below, to being illustrated according to the multiple mobile communication equipment that device of the present invention constituted.

RF direct amplifying station:

When front end module 310 was held module 410 for the alms giver, device 300 can constitute RF direct amplifying station 400.Fig. 4 is the structural representation that constitutes RF direct amplifying station according to device of the present invention.

As can be seen from Figure 4, front-end module 310 comprises that the alms giver holds module 410, and the alms giver holds module 410 to comprise control unit 411, radio-frequency channel 412 and clock unit 413.Control unit 411 is made up of central processing unit and telecommunication unit, is used for the operating state of control appliance, and the transmission of the state information of collecting device each several part and device management information; Radio-frequency channel 412 comprises low-converter on the radio frequency, divides mixer, power amplifier and low noise amplifier, mainly finishes the translation function of alms giver's end-fire frequency signal and intermediate-freuqncy signal; Clock unit 413 comprises clock source and some frequency synthesizers of high stable, is used to produce the alms giver and holds the required reference clock of module each several part, and reference clock is delivered to user side module 320 clock units 323 by the clock interface of standard.

As can be seen from Figure 4, the alms giver holds module 410 control units 411 and alms giver to hold module 410 radio-frequency channels 412 to be connected, the alms giver holds module 410 clock units 413 and alms giver to hold module 410 radio-frequency channels 412 to be connected, and the alms giver holds the equipment side of module 410 radio-frequency channels 412 to hold antenna to be connected with the alms giver.

RF direct amplifying station 400 comprises that mainly the alms giver holds module 410 and user side module 320.The alms giver holds module 410 radio-frequency channels 412 to hold antenna to be connected with the alms giver, the alms giver holds module 410 control units 411 to be connected with user side module 320 control units 321, the alms giver holds module 410 radio-frequency channels 412 to be connected with user side module 320 radio-frequency channels 322, the alms giver holds module 410 clock units 413 to be connected with user side module 320 clock units 323, and the antenna side of user side module 320 radio-frequency channels 322 is connected with the user side antenna.

The operation principle of this RF direct amplifying station 400 is as follows: at down direction, the alms giver holds antenna to receive the downstream signal of base station, the alms giver holds module 410 radio-frequency channels 412 to finish the work of radiofrequency signal amplification down-conversion, interface by intermodule is sent to user side module 320, finish upconversion process in user side module 320 radio-frequency channels 322, launch by the user side antenna; At up direction, the user side antenna receives user's mobile phone signal, through being converted to intermediate-freuqncy signal after 322 down-conversions of user side module 320 radio-frequency channels, be sent to the alms giver by intermodule interface and hold module 410, transmit go back to the base station after holding module 410 radio-frequency channels 412 up-conversions by the alms giver again.

The regular maintenance information of this RF direct amplifying station 400 is held the telecommunication unit in the control unit 411 of module 410 to obtain and is reported by the alms giver.The control of RF direct amplifying station 400 inside holds the control unit of module 410 and user side module 320 to realize by the alms giver.The alms giver holds the clock unit 413 of module 410 to produce the clock signal of a standard, and it is unified to make RF direct amplifying station 400 clock internal obtain.The alms giver holds the clock unit 323 of the clock unit 413 of module 410 and user side module 320 also to be used for to inside modules tranmitting data register signal separately.

The optical fiber repeater far-end:

When the front-end module 310 of device 300 was made up of optical interface module 510 and intermediate frequency process module 520, device 300 can constitute the optical fiber repeater far-end.Fig. 5 is the structural representation that constitutes the optical fiber repeater far-end according to device of the present invention.

As can be seen from Figure 5, intermediate frequency process module 520 comprises control unit 521, digital signal processing unit 522, modulus/D/A conversion unit 523, radio-frequency channel 524 and clock unit 525.Control unit 521 comprises central processing unit, is used for the operating state of control appliance, and the state information of collecting device each several part; Digital signal processing unit 522 comprises digital private processor or scale programmable logic device, finishes the frequency adaptation function of digital signal; Modulus/D/A conversion unit 523 comprises D and D/A converter, mainly finishes the translation function of analog signal and digital signal; Radio-frequency channel 524 comprises low-converter on the radio frequency, divides mixer, power amplifier, filter and low noise amplifier, mainly finishes the translation function of radiofrequency signal and intermediate-freuqncy signal; Clock unit 525 comprises frequency synthesizer, and the reference clock that transmits with optical interface module 510 is a reference source, produces the required reference clock of intermediate frequency process module 520 each several parts.

As can be seen from Figure 5, control unit 521 is connected with radio-frequency channel 524 with digital signal processing unit 522 respectively, clock unit 525 is connected with digital signal processing unit 522, modulus/D/A conversion unit 523 and radio-frequency channel 524 respectively, digital signal processing unit 522 is connected with modulus/D/A conversion unit 523, and modulus/D/A conversion unit 523 is connected with radio-frequency channel 524.

As can be seen from Figure 5, optical interface module 510 comprises control unit 511, digital signal processing unit 513, photoelectric conversion unit 512 and clock unit 514.Control unit 511 comprises central processing unit, the operating state that is used for control appliance, and the state information digital signal processing unit 513 of collecting device each several part comprises digital private processor or scale programmable logic device, finishes the extraction of control information, insertion function and the digital uplink signal of user side antenna and the pooling function of this equipment digital uplink signal of response message; Photoelectric conversion unit 512 comprises optical transceiving device and high-speed transfer device, be used to receive digital information downlink that comes from the optical fiber repeater near-end and the upstream digital information that comes from the user side antenna, and to optical fiber repeater near-end transmission upstream digital information and to user side antenna converting downlink digital information; Clock unit 514 comprises clock source and some frequency synthesizers of high stability, be used to produce the required reference clock of optical interface module 510 each several parts, and reference clock information sent to the clock unit 525 of intermediate frequency process module 520 by the clock interface of standard.

As can be seen from Figure 5, optical interface module 510 control units 511 are connected with photoelectric conversion unit 512 with digital signal processing unit 513 respectively, clock unit 514 is connected with digital signal processing unit 513, and photoelectric conversion unit 512 is connected with clock unit 514 with digital signal processing unit 513 respectively.

Optical fiber repeater far-end 500 mainly comprises optical interface module 510, intermediate frequency process module 520 and user side module 320.Optical interface module 510 photoelectric conversion units 512 are connected with the optical fiber repeater far-end of optical fiber repeater near-end or upper level cascade, optical interface module 510 control units 511 are connected with intermediate frequency process module 520 control units 521, optical interface module 510 digital signal processing units 513 are connected with intermediate frequency process module 520 digital signal processing units 522, optical interface module 510 clock units 514 are connected with intermediate frequency process module 520 clock units 525, intermediate frequency process module 520 control units 521 are connected with user side module 320 control units 321, intermediate frequency process module 520 radio-frequency channels 524 are connected with the front of user side module 320 radio-frequency channels 322, intermediate frequency process module 520 clock units 525 are connected with user side module 320 clock units 323, and the antenna side of user side module 320 radio frequency units 322 is connected with the user side antenna.

The operation principle of this optical fiber repeater far-end 500 is as follows: at down direction, photoelectric conversion unit 512 receives downgoing baseband signal or the descending intermediate-freuqncy signal that is transmitted by the optical fiber repeater near-end, in this signal, comprised control information to optical fiber repeater far-end 500, in digital signal processing unit 513, data speed is adjusted, and therefrom isolate control information to repeater far-end 500, downgoing baseband signal or descending intermediate-freuqncy signal are sent to the digital signal processing unit 522 of intermediate frequency process module 520 by the interface of intermodule, modulus/D/A conversion unit 523 through intermediate frequency process module 520 is converted to analog signal, is launched by the user side antenna system after upconversion process is finished in user side module 320 radio-frequency channels 322; At up direction, the user side antenna system receives user's mobile phone signal, be converted to digital signal through the modulus/D/A conversion unit 523 through intermediate frequency process module 520 after 322 down-conversions of user side module 320 radio-frequency channels, digital signal processing unit 522 in intermediate frequency process module 520 is finished Digital Signal Processing such as data rate adjustment, be sent to the digital signal processing unit 513 of optical interface module 510 by the interface of intermodule, the feedback information of optical fiber repeater far-end 400 and digital uplink signal framing again herein is through being sent to the optical fiber repeater far-end of optical fiber repeater near-end or upper level cascade by photoelectric conversion unit 512 after the rate adapted.

The operating state of this optical fiber repeater far-end 500 is controlled by the control unit of optical interface module 510, intermediate frequency process module 520 and user side module 320, and is collected the state information of each several part by these control units.The clock reference information that the optical fiber repeater far-end that the clock unit 513 of optical interface module 510 recovers optical fiber repeater near-end or upper level cascade transmits with data, produce the required reference clock of optical interface module 510 each several parts, and reference clock is sent to intermediate frequency process module 520.The clock unit of intermediate frequency process module 520 and user side module 320 receives the standard clock signal that optical interface module 510 transmits.The clock unit of three modules also is used for respectively to the inside tranmitting data register signal of module separately.

Radio frequency remote equipment:

When front end module 310 was made up of optical interface module 510 and intermediate frequency process module 520, this device 300 also can constitute radio frequency remote equipment 600.Fig. 6 is the structural representation that constitutes radio frequency remote equipment according to device of the present invention.

As can be seen from Figure 6, radio frequency remote equipment 600 is the same with optical fiber repeater far-end 500, also comprises optical interface module 510, intermediate frequency process module 520 and user side module 320.Different is, optical interface module 510 photoelectric conversion units 512 of radio frequency remote equipment 600 are connected with the radio frequency remote equipment of base station or upper level cascade by a digital optical interface, and optical interface module 510 photoelectric conversion units 512 of optical fiber repeater far-end are connected by the optical fiber repeater far-end of digital interface with optical fiber repeater near-end and upper level cascade.

The optical interface module 510 and optical interface module 510 indistinction on hardware that is used for radio frequency remote equipment 600 that are used for optical fiber repeater far-end 500, difference only is the software section in the digital signal processing unit 513, because being digital medium-frequency signals, the input signal of optical fiber repeater far-end 500 adds far-end control maintenance information, add the control maintenance information and the input signal of radio frequency remote equipment 600 is digital baseband signals, the Digital Transmission speed of two kinds of input signals is different.But the input signal of the input signal of optical fiber repeater far-end 500 and radio frequency remote equipment 600 can obtain identical Digital Transmission speed by Digital Signal Processing.

The operation principle of this radio frequency remote equipment 600 is as follows: at down direction, photoelectric conversion unit 512 receives downgoing baseband signal or the descending intermediate-freuqncy signal that is transmitted by the base station, in this signal, comprised control information to radio frequency remote equipment 600, downgoing baseband signal or descending intermediate-freuqncy signal are sent to Digital Signal Processing Unit 522 of intermediate frequency process module 520 by the interface of intermodule, modulus/D/A conversion unit 523 through intermediate frequency process module 520 is finished digital-to-analogue conversion, is launched by the user side antenna system after upconversion process is finished in the radio-frequency channel 322 of user side module 320; At up direction, the user side antenna system receives the user mobile phone signal, modulus/D/A conversion unit 523 of delivering to intermediate frequency process module 520 after radio-frequency channel 322 down-conversions through user side module 320 is converted to digital signal, in intermediate frequency process module 520 digital signal processing units 522, finish Digital Signal Processing such as data rate adjustment, be sent to the digital signal processing unit 513 of optical interface module 510 by the interface of intermodule, the feedback information of radio frequency remote equipment 600 and digital uplink signal framing again sends to the base station through after the rate adapted by photoelectric conversion unit 512 herein.

The operating state of this radio frequency remote equipment 600 is controlled by the control unit of optical interface module 510, intermediate frequency process module 520 and user side module 320, and is collected the state information of each several part by these control units.The clock reference information that the radio frequency remote equipment that the clock unit 514 of optical interface module 510 recovers base station or upper level cascade transmits with data, produce the required reference clock of optical interface module 510 each several parts, and reference clock is sent to intermediate frequency process module 520 clock units 525, the clock unit of intermediate frequency process module 520 and user side module 320 receives the standard clock signal that optical interface module 510 transmits.The clock unit of three modules also is used for respectively to the inside tranmitting data register signal of module separately.

Little base station:

When front end module 310 was made up of with intermediate frequency process module 520 transport module 710, base station baseband module 720, device 300 can constitute little base station 700.Fig. 7 is the structural representation that device according to the present invention constitutes little base station.

As can be seen from Figure 7, transport module 710 comprises transmission unit 711, transmission unit 711 is used to provide the interface with Radio Link Controller, be used to carry out photoelectricity/electric light conversion, when the signal that transmits from Radio Link Controller was digital optical signal, transmission unit 711 was converted to digital electric signal with this digital optical signal.The transmission unit 711 of transport module 710 can provide E1/T1 Interface, SDH (Synchronous Digital Hierarchy) (SDH) interface and x Digital Subscriber Line (xDSL) interface.But, if the signal that transmits from Radio Link Controller is a digital electric signal, need not so to change, that is to say, in the case, do not need this transport module 710 to change.

As can be seen from Figure 7, base station baseband module 720 comprises control unit 721, digital signal processing unit 723, base station controller interface unit 722 and clock unit 724.The control unit 721 of base station baseband module 720 comprises central processing unit, is used to finish Node B application protocol (NBAP) signaling process, resource management and Operation and Maintenance function, realizes the monitoring to the base station operating state, and I/O control interface in base station is provided.The digital signal processing unit 723 of base station baseband module 720 comprises digital private processor or scale programmable logic device, finishes base band signal process.The base station controller interface unit 722 of base station baseband module 720 comprises special-purpose processor and extensive logic and signal processor, be used for transmission unit 711 received frame agreements (FP) bag from transport module 710, under the configuration of high level, carry out chnnel coding, descending modulation, power adjustment, close road etc., finish data rate; Receive upstream data from the digital signal processing unit 522 of intermediate frequency processing module 520, finish demodulation, decoding processing, transport channel content is passed to transmission unit 711 with the FP packet format; And physics closed-loop process, comprise that the closed-loop process of catching indication (AI) information, up-downgoing physical layer closed power control and treatment, descending Closed-Loop Transmit Diversity handle, these closed loop procedure all are the control information that demodulation obtains being correlated with from the information of up reception (AI, uplink transmit power control (TPC), downlink transmission power control (TPC) and feedback informations (FBI)), these information are directly passed to descending sendaisle then, and descending sendaisle will use these information on request.The clock unit 724 of base station baseband module 720 comprises clock source and some frequency synthesizers of high stability, be used to produce the required reference clock of base station baseband module 720 each several parts, and reference clock signal be sent to the clock unit 525 of intermediate frequency process module 520 by the clock interface of standard.

As can be seen from Figure 7, in base station baseband module 720, control unit 721 is connected with digital signal processing unit 723 with base station controller interface unit 722 respectively, base station controller interface unit 722 is connected with clock unit 724 with digital signal processing unit 723 respectively, and clock unit 724 is connected with digital signal processing unit 723.

As can be seen from Figure 7, little base station 700 mainly comprises transport module 710, base station baseband module 720, intermediate frequency process module 520 and user side module 320.The upper level equipment side of transport module 710 transmission units 711 is connected with Radio Link Controller, the base station baseband side of transport module 710 transmission units 711 is connected with base station baseband module 720 base station controller interface units 722, base station baseband module 720 control units 721 are connected with intermediate frequency process module 520 control units 521, base station baseband module 720 Digital Signal Processing Unit 723 are connected with intermediate frequency process module 520 digital signal processing units 522, base station baseband module 720 clock units 724 are connected with intermediate frequency process module 520 clock units 525, intermediate frequency process module 520 control units 521 are connected with user side module 320 control units 321, intermediate frequency process module 520 radio-frequency channels 524 are connected with user side module 320 radio-frequency channels 322, intermediate frequency process module 520 clock units 525 are connected with user side module 320 clock units 323, and the antenna side of user side module 320 radio-frequency channels 322 is connected with the user side antenna.

The operation principle of this little base station 700 is as follows: at down direction, transport module 710 is from the Radio Link Controller acquired information, finish descending modulation, power adjustment, close road etc. through base station baseband module 720, form baseband signal, the downgoing baseband signal is sent to the digital signal processing unit 522 of intermediate frequency process module 520 by the interface of intermodule, modulus/D/A conversion unit 523 through intermediate frequency process module 520 is converted to analog signal, upconversion process is finished in radio-frequency channel 322 in user side module 320, is launched by the user side antenna; At down direction, the mobile phone signal of user side antenna receiving mobile, after 322 down-conversions of user side module 320 radio-frequency channels, and the modulus/D/A conversion unit 523 of process intermediate frequency process module 520 is converted to digital signal, digital signal processing unit 522 in IF processing unit 520 is finished Digital Signal Processing such as data rate adjustment, form the uplink baseband data, interface by intermodule transfers to base station baseband module 720, finish demodulation, decoding is handled, with the FP packet format transport channel content is passed to the transmission unit 711 of transport module 710, transmission unit 711 is sent to Radio Link Controller with the content of transmission channel.

The control unit 721 of base station baseband module 720 is finished NBAP signaling process, resource management and Operation and Maintenance function, realizes the monitoring to the base station operating state, and the base station input/output interface is provided.The control unit of base station baseband module 720, intermediate frequency process module 520 and user side module 320 is monitored the state of little base station 700 each several parts, and collects the state information of each several part.The clock unit 724 of base station baseband module 720 produces the required reference clock of base station baseband module 720 each several parts, and reference clock delivered to the clock unit of intermediate frequency process module 520 and user side module 320 by the clock interface of standard, so that the clock unit of intermediate frequency process module 520 and user side module 320 sends reference clock to separately inside modules.

In concrete implementation process, can carry out suitable improvement, to adapt to the concrete needs of concrete condition to the method according to this invention.Therefore be appreciated that; just play an exemplary role according to the specific embodiment of the present invention; not in order to restriction protection scope of the present invention; for example; device of the present invention not only can constitute RF direct amplifying station, optical fiber repeater far-end, radio frequency remote equipment and little base station as mentioned above, also can constitute other mobile communication equipment.

Claims (14)

1. a mobile communication equipment is characterized in that, described mobile communication equipment is a RF direct amplifying station,

Described RF direct amplifying station comprises:

Front-end module (310), be used to receive the downlink radio-frequency signal of holding antenna from the alms giver, be sent to user side module (320) after described downlink radio-frequency signal is converted to descending intermediate-freuqncy signal, and receive up intermediate-freuqncy signal from user side module (320), described up intermediate-freuqncy signal is converted to is sent to the alms giver after the up radiofrequency signal and holds antenna;

User side module (320), be used to receive up radiofrequency signal from the user side antenna, be sent to front-end module (310) after described up radiofrequency signal is converted to up intermediate-freuqncy signal, and receive descending intermediate-freuqncy signal from front-end module (310), after being converted to downlink radio-frequency signal, described descending intermediate-freuqncy signal is sent to the user side antenna;

Wherein, front-end module (310) comprising:

Front-end module control channel (311), being used for forward end module by signal treatment channel (312) sends control information, reception is from the state information of front-end module signal processing channel (312), reception is from the reference clock of front-end module clock passage (313), by standard digital interface and user side module control unit (321) transmitting control information;

Front-end module signal processing channel (312), be used for forward end module controls passage (311) send state information, reception is from the control information of front-end module control channel (311), reception is from the reference clock of front-end module clock passage (313), the downlink radio-frequency signal of antenna is held in reception from the alms giver, be sent to user side module radio-frequency channel (322) after described downlink radio-frequency signal is converted to descending intermediate-freuqncy signal, reception is from the up intermediate-freuqncy signal of user side module radio-frequency channel (322), described up intermediate-freuqncy signal is converted to be sent to the alms giver after the up radiofrequency signal and hold antenna; And

Front-end module clock passage (313) is used to produce the required reference clock of front-end module (310), and forward end module controls passage (311) and front-end module signal processing channel (312) send reference clock,

User side module (320) comprising:

User side module control unit (321), be used for sending control information to user side module radio-frequency channel (322), reception is from the state information of user side module radio-frequency channel (322), reception is from the reference clock of user side module clock unit (323), by standard digital interface and front-end module control channel (311) transmitting control information;

User side module radio-frequency channel (322), be used for to user side module control unit (321) send state information, reception is from the control information of user side module control unit (321), reception is from the reference clock of user side module clock unit (323), by the descending intermediate-freuqncy signal of standard analog interface reception from front-end module signal processing channel (312), be sent to the user side antenna after described descending intermediate-freuqncy signal is converted to downlink radio-frequency signal, reception is from the up radiofrequency signal of user side antenna, is sent to front-end module signal processing channel (312) by the standard analog interface after described up radiofrequency signal is converted to up intermediate-freuqncy signal; And

User side module clock unit (323), being used for the clock reference signal from front-end module clock passage (313) that receives is that benchmark produces the required reference clock of user side module (320), sends reference clock to user side module control unit (321) and user side module radio-frequency channel (322).

2. mobile communication equipment according to claim 1 is characterized in that, front-end module control channel (311) is held module control unit (411) for the alms giver;

Front-end module signal processing channel (312) is held module radio-frequency channel (412) for the alms giver;

Front-end module clock passage (313) is held module clock unit (413) for the alms giver.

3. mobile communication equipment according to claim 2 is characterized in that, the alms giver holds module control unit (411) to comprise interconnected central processing unit and telecommunication unit; The alms giver holds module radio-frequency channel (412) to comprise low-converter on the radio frequency that connects successively, divides mixer, power amplifier, filter and low noise amplifier; The alms giver holds module clock unit (413) to comprise interconnectedly to be used to provide the clock source of clock reference signal and to be used for holding module control unit (411) and alms giver to hold module radio-frequency channel (412) that the frequency synthesizer of clock signal is provided to the alms giver,

User side module control unit (321) comprises interconnected central processing unit and telecommunication unit; User side module radio-frequency channel (322) comprises low-converter on the radio frequency that connects successively, divides mixer, power amplifier, filter and low noise amplifier; User side module clock unit (323) is for being used for providing to user side module control unit (321) and user side module radio-frequency channel (322) frequency synthesizer of clock signal.

4. a mobile communication equipment is characterized in that, described mobile communication equipment is the optical fiber repeater far-end,

The optical fiber repeater far-end comprises:

Front-end module (310), be used to receive descending digital signal from the optical fiber repeater far-end of optical fiber repeater near-end or upper level cascade, be sent to user side module (320) after described descending digital signal is converted to descending intermediate-freuqncy signal, or the digital uplink signal of the optical fiber repeater far-end of reception next stage cascade, and with described digital uplink signal and the optical fiber repeater far-end of delivering to optical fiber repeater near-end or upper level cascade from the up intermediate-freuqncy signal hybrid concurrency of user side module (320);

User side module (320), be used for receiving descending intermediate-freuqncy signal from front-end module (310), be sent to the user side antenna after described descending intermediate-freuqncy signal is converted to downlink radio-frequency signal, with the up radiofrequency signal that receives from the user side antenna, be sent to front-end module (310) after described up radiofrequency signal is converted to up intermediate-freuqncy signal;

Wherein, front-end module (310) comprising:

Front-end module control channel (311), being used for forward end module by signal treatment channel (312) sends control information, reception is from the state information of front-end module signal processing channel (312), reception is from the reference clock of front-end module clock passage (313), by standard digital interface and user side module control unit (321) transmitting control information;

Front-end module signal processing channel (312), be used for forward end module controls passage (311) send state information, reception is from the control information of front-end module control channel (311), reception is from the reference clock of front-end module clock passage (313), reception is from the descending digital signal of the optical fiber repeater far-end of optical fiber repeater near-end or upper level cascade, be sent to user side module radio-frequency channel (322) after described descending digital signal is converted to descending intermediate-freuqncy signal, reception is from the up intermediate-freuqncy signal of user side module radio-frequency channel (322), with described up intermediate-freuqncy signal conversion digital uplink signal, and be treated to the optical fiber repeater far-end that is sent to optical fiber repeater near-end or upper level cascade behind the required signal of the optical fiber repeater far-end of optical fiber repeater near-end or upper level cascade; And

Front-end module clock passage (313) is used to produce the required reference clock of front-end module (310), and forward end module controls passage (311) and front-end module signal processing channel (312) send reference clock,

User side module (320) comprising:

User side module control unit (321), be used for sending control information to user side module radio-frequency channel (322), reception is from the state information of user side module radio-frequency channel (322), reception is from the reference clock of user side module clock unit (323), by standard digital interface and front-end module control channel (311) transmitting control information;

User side module radio-frequency channel (322), be used for to user side module control unit (321) send state information, reception is from the control information of user side module control unit (321), reception is from the reference clock of user side module clock unit (323), by the descending intermediate-freuqncy signal of standard analog interface reception from front-end module signal processing channel (312), be sent to the user side antenna after described descending intermediate-freuqncy signal is converted to downlink radio-frequency signal, reception is from the up radiofrequency signal of user side antenna, is sent to front-end module signal processing channel (312) by the standard analog interface after described up radiofrequency signal is converted to up intermediate-freuqncy signal; And

User side module clock unit (323), being used for the clock reference signal from front-end module clock passage (313) that receives is that benchmark produces the required reference clock of user side module (320), sends reference clock to user side module control unit (321) and user side module radio-frequency channel (322).

5. mobile communication equipment according to claim 4 is characterized in that, front-end module control channel (311) comprises interconnected optical interface module control unit (511) and intermediate frequency process module control unit (521),

Front-end module signal processing channel (312) comprises optical interface module photoelectric conversion unit (512), optical interface module digital signal processing unit (513), intermediate frequency process module digital signal processing unit (522), intermediate frequency process module modulus/D/A conversion unit (523) and the intermediate frequency process module radio-frequency channel (524) that connects successively

Front-end module clock passage (313) comprises interconnected optical interface module clock unit (514) and intermediate frequency process module clock unit (525).

6. mobile communication equipment according to claim 5 is characterized in that, optical interface module control unit (511) is a central processing unit; Optical interface module photoelectric conversion unit (512) comprises interconnected optical transceiving device and high-speed transfer device; Optical interface module digital signal processing unit (513) is digital private processor or scale programmable logic device; Optical interface module clock unit (514) comprises the interconnected frequency synthesizer that is used to provide the clock source of clock reference signal and is used for providing to optical interface module control unit (511), optical interface module photoelectric conversion unit (512) and optical interface module digital signal processing unit (513) clock signal

Intermediate frequency process module control unit (521) is a central processing unit; Intermediate frequency process module digital signal processing unit (522) is digital private processor or scale programmable logic device; Intermediate frequency process module modulus/D/A conversion unit (523) is a D and D/A converter; Intermediate frequency process module radio-frequency channel (524) comprises low-converter on the interconnected radio frequency, divides mixer, power amplifier, filter and low noise amplifier; Intermediate frequency process module clock unit (525) is for being used for providing to intermediate frequency process module control unit (521), intermediate frequency process module digital signal processing unit (522), intermediate frequency process module modulus/D/A conversion unit (523) and intermediate frequency process module radio-frequency channel (524) frequency synthesizer of clock signal

User side module control unit (321) comprises interconnected central processing unit and telecommunication unit; User side module radio-frequency channel (322) comprises low-converter on the radio frequency that connects successively, divides mixer, power amplifier, filter and low noise amplifier; User side module clock unit (323) is for being used for providing to user side module control unit (321) and user side module radio-frequency channel (322) frequency synthesizer of clock signal.

7. a mobile communication equipment is characterized in that, described mobile communication equipment is a radio frequency remote equipment,

Radio frequency remote equipment comprises:

Front-end module (310), be used to receive descending digital signal from the radio frequency remote equipment of base station or upper level cascade, be sent to intermediate frequency process module (520) after described descending digital signal is converted to descending intermediate-freuqncy signal, or the digital uplink signal of the radio frequency remote equipment of reception next stage cascade, and with described digital uplink signal and the radio frequency remote equipment that send base station or upper level cascade from the up intermediate-freuqncy signal hybrid concurrency of user side module (320);

User side module (320), be used for receiving descending intermediate-freuqncy signal from front-end module (310), be sent to the user side antenna after described descending intermediate-freuqncy signal is converted to downlink radio-frequency signal, with the up radiofrequency signal that receives from the user side antenna, be sent to front-end module (310) after described up radiofrequency signal is converted to up intermediate-freuqncy signal;

Wherein, front-end module (310) comprising:

Front-end module control channel (311), being used for forward end module by signal treatment channel (312) sends control information, reception is from the state information of front-end module signal processing channel (312), reception is from the reference clock of front-end module clock passage (313), by standard digital interface and user side module control unit (321) transmitting control information;

Front-end module signal processing channel (312), be used for forward end module controls passage (311) send state information, reception is from the control information of front-end module control channel (311), reception is from the reference clock of front-end module clock passage (313), reception is from the descending digital signal of the radio frequency remote equipment of base station or upper level cascade, be sent to user side module radio-frequency channel (322) after described descending digital signal is converted to descending intermediate-freuqncy signal, reception is from the up intermediate-freuqncy signal of user side module radio-frequency channel (322), described up intermediate-freuqncy signal is converted to digital signal, and is treated to the radio frequency remote equipment that is sent to base station or upper level cascade behind the required signal of the radio frequency remote equipment of base station or upper level cascade; And

Front-end module clock passage (313) is used to produce the required reference clock of front-end module (310), and forward end module controls passage (311) and front-end module signal processing channel (312) send reference clock,

User side module (320) comprising:

User side module control unit (321), be used for sending control information to user side module radio-frequency channel (322), reception is from the state information of user side module radio-frequency channel (322), reception is from the reference clock of user side module clock unit (323), by standard digital interface and front-end module control channel (311) transmitting control information;

User side module radio-frequency channel (322), be used for to user side module control unit (321) send state information, reception is from the control information of user side module control unit (321), reception is from the reference clock of user side module clock unit (323), by the descending intermediate-freuqncy signal of standard analog interface reception from front-end module signal processing channel (312), be sent to the user side antenna after described descending intermediate-freuqncy signal is converted to downlink radio-frequency signal, reception is from the up radiofrequency signal of user side antenna, is sent to front-end module signal processing channel (312) by the standard analog interface after described up radiofrequency signal is converted to up intermediate-freuqncy signal; And

User side module clock unit (323), being used for the clock reference signal from front-end module clock passage (313) that receives is that benchmark produces the required reference clock of user side module, sends reference clock to user side module control unit (321) and user side module radio-frequency channel (322).

8. mobile communication equipment according to claim 7 is characterized in that, front-end module control channel (311) comprises interconnected optical interface module control unit (511) and intermediate frequency process module control unit (521),

Front-end module signal processing channel (312) comprises optical interface module photoelectric conversion unit (512), optical interface module digital signal processing unit (513), intermediate frequency process module digital signal processing unit (522), intermediate frequency process module modulus/D/A conversion unit (523) and the intermediate frequency process module radio-frequency channel (524) that connects successively

Front-end module clock passage (313) comprises interconnected optical interface module clock unit (514) and intermediate frequency process module clock unit (525).

9. mobile communication equipment according to claim 8 is characterized in that, optical interface module control unit (511) is a central processing unit; Optical interface module photoelectric conversion unit (512) comprises interconnected optical transceiving device and high-speed transfer device; Optical interface module digital signal processing unit (513) is digital private processor or scale programmable logic device; Optical interface module clock unit (514) comprises the interconnected frequency synthesizer that is used to provide the clock source of clock reference signal and is used for providing to optical interface module control unit (511), optical interface module photoelectric conversion unit (512) and optical interface module digital signal processing unit (513) clock signal

Intermediate frequency process module control unit (521) is a central processing unit; Intermediate frequency process module digital signal processing unit (522) is digital private processor or scale programmable logic device; Intermediate frequency process module modulus/D/A conversion unit (523) is a D and D/A converter; Intermediate frequency process module radio-frequency channel (524) comprises low-converter on the interconnected radio frequency, divides mixer, power amplifier, filter and low noise amplifier; Intermediate frequency process module clock unit (525) is for being used for providing to intermediate frequency process module control unit (521), intermediate frequency process module digital signal processing unit (522), intermediate frequency process module modulus/D/A conversion unit (523) and intermediate frequency process module radio-frequency channel (524) frequency synthesizer of clock signal

User side module control unit (321) comprises interconnected central processing unit and telecommunication unit; User side module radio-frequency channel (322) comprises low-converter on the radio frequency that connects successively, divides mixer, power amplifier, filter and low noise amplifier; User side module clock unit (323) is for being used for providing to user side module control unit (321) and user side module radio-frequency channel (322) frequency synthesizer of clock signal.

10. a mobile communication equipment is characterized in that, described mobile communication equipment is little base station,

Little base station comprises:

Front-end module (310), be used to receive descending digital signal from base station controller, described descending encoding digital signals, descending modulation treatment are formed baseband signal, and be sent to user side module (320) after being converted to descending analog intermediate frequency signal, with the up intermediate-freuqncy signal that receives from user side module (320), described up intermediate-freuqncy signal is converted to digital signal, and carries out being sent to base station controller after uplink demodulation, the decoding processing;

User side module (320), be used to receive up radiofrequency signal from the user side antenna, be sent to front-end module (310) after described up radiofrequency signal is converted to up intermediate-freuqncy signal, with the descending analog intermediate frequency signal that receives from front-end module (310), be sent to the user side antenna after described descending analog intermediate frequency signal is converted to downlink radio-frequency signal;

Wherein, front-end module (310) comprising:

Front-end module control channel (311), being used for forward end module by signal treatment channel (312) sends control information, reception is from the state information of front-end module signal processing channel (312), reception is from the reference clock of front-end module clock passage (313), by standard digital interface and user side module control unit (321) transmitting control information;

Front-end module signal processing channel (312), be used for forward end module controls passage (311) send state information, reception is from the control information of front-end module control channel (311), reception is from the reference clock of front-end module clock passage (313), reception is from the descending digital signal of base station controller, be sent to user side module radio-frequency channel (322) after described descending digital signal is converted to descending analog intermediate frequency signal, reception is from the up intermediate-freuqncy signal of user side module radio-frequency channel (322), described up intermediate-freuqncy signal is converted to digital signal, and is sent to base station controller after being treated to the required signal of base station controller; And

Front-end module clock passage (313) is used to produce the required reference clock of front-end module (310), and forward end module controls passage (311) and front-end module signal processing channel (312) send reference clock,

User side module (320) comprising:

User side module control unit (321), be used for sending control information to user side module radio-frequency channel (322), reception is from the state information of user side module radio-frequency channel (322), reception is from the reference clock of user side module clock unit (323), by standard digital interface and front-end module control channel (311) transmitting control information;

User side module radio-frequency channel (322), be used for to user side module control unit (321) send state information, reception is from the control information of user side module control unit (321), reception is from the reference clock of user side module clock unit (323), by the descending analog intermediate frequency signal of standard analog interface reception from front-end module signal processing channel (312), be sent to the user side antenna after described descending analog intermediate frequency signal is converted to downlink radio-frequency signal, reception is from the up radiofrequency signal of user side antenna, is sent to front-end module signal processing channel (312) by the standard analog interface after described up radiofrequency signal is converted to up intermediate-freuqncy signal; And

User side module clock unit (323), being used for the clock reference signal from front-end module clock passage (313) that receives is that benchmark produces the required reference clock of user side module (320), sends reference clock to user side module control unit (321) and user side module radio-frequency channel (322).

11. mobile communication equipment according to claim 10 is characterized in that, front-end module control channel (311) comprises interconnected base station baseband module control unit (721) and intermediate frequency process module control unit (521),

Front-end module signal processing channel (312) comprises base station baseband module base station controller interface unit (722), base station baseband module digital signal processing unit (723), intermediate frequency process module digital signal processing unit (522), intermediate frequency process module modulus/D/A conversion unit (523) and the intermediate frequency process module radio-frequency channel (524) that connects successively

Front-end module clock passage (313) comprises interconnected base station baseband module clock unit (724) and intermediate frequency process module clock unit (525).

12. mobile communication equipment according to claim 11 is characterized in that, base station baseband module control unit (721) is a central processing unit; Base station baseband module base station controller interface unit (722) comprises interconnected coder/decoder, modulator/demodulator and power regulator spare; Base station baseband module digital signal processing unit (723) is digital private processor or scale programmable logic device; Base station baseband module clock unit (724) comprises the interconnected frequency synthesizer that is used to provide the clock source of clock reference signal and is used for providing to base station baseband module control unit (721), base station baseband module base station controller interface unit (722) and base station baseband module digital signal processing unit (723) clock signal

Intermediate frequency process module control unit (521) is a central processing unit; Intermediate frequency process module digital signal processing unit (522) is digital private processor or scale programmable logic device; Intermediate frequency process module modulus/D/A conversion unit (523) is a D and D/A converter; Intermediate frequency process module radio-frequency channel (524) comprises low-converter on the interconnected radio frequency, divides mixer, power amplifier, filter and low noise amplifier; Intermediate frequency process module clock unit (525) is for being used for providing to intermediate frequency process module control unit (521), intermediate frequency process module digital signal processing unit (522), intermediate frequency process module modulus/D/A conversion unit (523) and intermediate frequency process module radio-frequency channel (524) frequency synthesizer of clock signal

User side module control unit (321) comprises interconnected central processing unit and telecommunication unit; User side module radio-frequency channel (322) comprises low-converter on the radio frequency that connects successively, divides mixer, power amplifier, filter and low noise amplifier; User side module clock unit (323) is for being used for providing to user side module control unit (321) and user side module radio-frequency channel (322) frequency synthesizer of clock signal.

13. mobile communication equipment according to claim 11, it is characterized in that, front-end module signal processing channel (312) further comprises transport module transmission unit (711), be used for to be converted to from the descending digital optical signal of base station and be sent to base station baseband module base station controller interface unit (722) behind the digital electric signal and will be to be sent to the base station behind the digital optical signal from the upstream digital electrical signal conversion of base station baseband module base station controller interface unit (722).

14. mobile communication equipment according to claim 13 is characterized in that, transport module transmission unit (711) comprises the switching device of digital optical signal and digital electric signal and the switching device of digital electric signal and digital optical signal.

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