CN1529522A - Multi-carrier transmssion digital merging device - Google Patents
Multi-carrier transmssion digital merging device Download PDFInfo
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Abstract
The device comprises band-pass filter, amplifier, linear power amplifier, local oscillation source, baseband digital merging module, two identical D/A converters and I/Q modulator. Input baseband digital I/Q signals In(n) and Qn(n) to be processed are input to the baseband digital merging module, where digital merging operation in baseband is carried out. Merged output baseband digital I/Q is I(n) and Q(n), which pass through a D/A converter, are converted to analog I/Q signal. The said I/Q signal modulated by I/Q modulator is sent to band-pass filter and amplifier to be filtered and amplified. Finally, the amplified signal is sent to linear power amplifier. The invented device simplifies designing of multicarrier transmitting chain, raises reliability of system and reduces workload for debugging system. Comparing with mode of digital processing in medium frequency, the mode used in the invention gives less difficulty to designing subsequent stage of analog circuit.
Description
Technical field
The present invention relates to field of mobile communication, relate in particular to mobile communcations system multicarrier emission numeral and close the road device.
Background technology
The live and work that affects people that mobile communcations system is more and more deep designs a kind of low cost, high-quality mobile communcations system, has become one of problem that present mobile communication equipment manufacturer must take in.In mobile communication system, multicarrier transmitter is an indispensable part, and its performance quality directly affects the performance of whole system.In the multicarrier transmitter of mobile communcations system, generally multi-carrier signal need be closed the road and handle in transmitting chain, realize that at present closing the road mainly contains dual mode.First kind of mode is that traditional analog radio frequency closes the road mode, the method that is about to analog baseband signal process one or many simulation up-conversion is modulated to radiofrequency signal, closes the road at radio frequency then and exports linear power amplifier (Linear Power Amplifier) to.Such as, transmitting chain for 2 carrier wave WCDMA signals, close the mode on road with radio frequency, if adopt a up-conversion method as shown in Figure 1, the input base-band digital i/q signal of carrier wave 1 is I1 (n), Q1 (n), the input base-band digital i/q signal of carrier wave 2 is I2 (n), Q2 (n), the base-band digital i/q signal of 2 carrier waves is delivered to separately I/Q modulators modulate after through the D/A conversion to the radiofrequency signal of different frequency, through filtering, amplify back 2 tunnel single-carrier signal and close the road through a radio frequency mixer again, the radiofrequency signal of synthetic 1 tunnel 2 carrier wave is delivered to linear power amplifier.In the described mode of Fig. 1, need 2 local oscillation signals and 2 I/Q modulators, if emission is 3 carrier signals, then need 3 local oscillation signals and 3 I/Q modulation; As can be seen, the shortcoming of this mode is every increase by 1 carrier wave, just needs the signal processing link of corresponding increase by 1 road from the base band to the radio frequency; Use for multicarrier, this mode seems uneconomical, particularly the signal processing link of each carrier wave all will design the different frequency local oscillation circuit, has more increased the difficulty (as the factor of electromagnetic compatibility aspect) of physical circuit design, and circuit reliability reduces, debugging work load is big.
What the second way adopted is this relative newer technology of digital intermediate frequency path combining technique: the multicarrier baseband signal is handled by Digital Up Convert, every carrier wave baseband signal is arrived frequency translation the intermediate frequency of numeric field separately in numeric field, in numeric field, carry out addition then, the multi-carrier digital intermediate-freuqncy signal that obtains synthesizing, after process and the one or many simulation up-conversion, finally export radiofrequency signal.One concrete uses is 2 to close road 2 carrier wave WCDMA emission systems, its basic structure is as shown in Figure 2: the input base-band digital i/q signal of carrier wave 1 is I1 (n), Q1 (n), the input base-band digital i/q signal of carrier wave 2 is I2 (n), Q2 (n), the input base-band digital i/q signal of 2 carrier waves all inputs to a Digital IF Processing module and handles, in this module, carry out digital intermediate frequency and close the road, after closing the D/A converter of road output high-speed digital signal through 1 high speed, become 2 carrier wave analog intermediate frequency signals, through up-conversion after the mixing to radio frequency, filtering then, deliver to linear power amplifier after the amplification.The shortcoming of this mode is that requirement to device performance is than higher, because the multi-carrier digital intermediate-freuqncy signal data rate that should export is very high usually, need to be transformed into the multicarrier analog if signal through D/A converter at a high speed, simultaneously because the restriction of Digital Up Convert processor processing speed at present, the intermediate frequency of its output generally can only reach 20-30MHz at present, and, to just can obtain final radiofrequency signal through the processing of 2 simulation up-conversions usually because the output intermediate frequency is low; If adopt high performance Digital Up Convert processor and D/A converter, though also can improve D/A converter output intermediate frequency (as reaching about 70MHz), but the index when the index specific output intermediate frequency of at this moment exporting intermediate-freuqncy signal is 20-30MHz has bigger deterioration, for guaranteeing the performance index of whole system, require to improve the performance index of back level simulation process link, this has strengthened the design difficulty of back level analog processing circuit undoubtedly.
Summary of the invention
The objective of the invention is to overcome the shortcoming that the circuit design difficulty is big, system reliability is low, performance index worsen easily of existing two kinds of technology, provide a kind of can the realization that the multicarrier emission numeral of the synthetic 1 roadbed band numeral of multicarrier base-band digital i/q signal i/q signal is closed the road device.
For achieving the above object, the present invention has constructed a kind of multicarrier emission numeral and has closed the road device, comprise band pass filter, amplifier, linear power amplifier, local vibration source, it is characterized in that, comprise that also base-band digital closes road module, two identical D/A converters, I/Q modulator;
The input base-band digital i/q signal In (n) of each carrier wave and Qn (n) input to described base-band digital and close the road processing module and handle, in this module, carry out base-band digital and close dataway operation, the base-band digital I/Q of ECDC road output is I (n), Q (n), I (n), Q (n) are respectively through converting Simulation with I/Q signal to behind the D/A converter then, carry out I/Q through described I/Q modulator and be modulated to radio frequency, carry out filtering through described band pass filter then, described amplifier carries out delivering to described linear power amplifier after the power amplification.
Close the road device for nd carrier emission numeral, described base-band digital closes the road module and comprises digital controlled oscillator (NCO, Numeric Control Oscillator), first digital multiplier, second digital multiplier, the 3rd digital multiplier, the 4th digital multiplier, first adder, second adder, the 3rd adder, the 4th adder, first subtracter and second subtracter; The vibration of described digital controlled oscillator is output as sine and cosine signal: sin (ω in) and the cos (ω in) that frequency is ω i, and its work clock is 15.36MHz, and ω in corresponds to 2.5MHz; The relation of input and output is as follows:
I(n)=[I1(n)+I2(n)]cos(ωin)+[Q1(n)-Q2(n)]sin(ωin)
(1)
Q(n)=[Q2(n)+Q1(n)]cos(ωin)+[I2(n)-I1(n)]sin(ωin)
(2)
I1 (n) and I2 (n) are through described second adder addition, and the cos of result and described digital controlled oscillator (ω in) output multiplication obtains output [I1 (n)+I2 (n)] cos (ω in) component; Q1 (n) and Q2 (n) subtract each other through described second subtracter, output again with sin (ω in) output multiplication of described digital controlled oscillator, obtain [Q1 (n)-Q2 (n)] sin (ω in) component, two parts obtain I (n) and export by described the 3rd adder addition;
Q1 (n) and Q2 (n) are through described first adder addition, and the cos of result and described digital controlled oscillator (ω in) output multiplication is output as [Q2 (n)+Q1 (n)] cos (ω in) component; I2 (n) and I1 (n) subtract each other through described second subtracter, output again with sin (ω in) output multiplication of described digital controlled oscillator, obtain [Q1 (n)-Q2 (n)] sin (ω in).Component, two parts obtain Q (n) output by described the 4th adder addition.
Described digital controlled oscillator mainly comprises phase accumulator and sine lookup table, and the phase value of described phase accumulator is that addition is carried out in stepping with phase-accumulated factor M under the effect of system works clock at every turn; The output phase value of phase accumulator is as the address input of sine lookup table; What deposited at the place, address in the described sine lookup table is exactly the sine value of this phase value correspondence; So just finish the conversion of phase place and amplitude.
Close the road device for nd carrier emission numeral, this three carrier transmit numeral is closed in the device of road the highest and nd carrier base-band digital I/Q lowest frequency points correspondence closes the road algorithm by nd carrier described above and handles (frequency of oscillation of NCO makes 5MHz into), the digital baseband I/Q that obtains nd carrier closes road output, then that the digital baseband i/q signal of this nd carrier is corresponding with intermediate frequency point carrier wave respectively again again base-band digital i/q signal is done addition, and the digital baseband I/Q that can obtain three carrier waves closes road output.
Described digital controlled oscillator adopts scale programmable logic device (FPGA) to realize, can utilize the RAM of FPGA inside or ROM memory resource to deposit sine lookup table.
Device of the present invention is handled by in baseband portion multicarrier base-band digital i/q signal being closed the road, synthetic 1 roadbed band numeral i/q signal; So, closing the road mode with radio frequency compares, the signal no matter device of the present invention is launched is single carrier or multicarrier, all only need 1 road signal processing link from the base band to the radio frequency, thereby brought very big simplification for the design of multicarrier transmitting chain, improve the reliability of system simultaneously, reduced the debugging work load of system greatly; In addition, closing the road mode with digital intermediate frequency compares, because the work clock speed of device of the present invention is lower, the D/A converter can adopt cheap low speed devices, close the road mode and must select at a high speed device for use and need not resemble digital intermediate frequency, and base band is closed the Digital Up Convert processing links of the high speed that the road mode need not be complicated.What base band closed that the road mode exports is baseband signal, and the device level of present analogue quadrature moducator has reached and baseband signal directly can be modulated to radio frequency output (promptly once simulating the up-conversion mode), this moment, local oscillation signal only needed one, compare with the Digital IF Processing mode, this mode gives the back pressure that the level Design of Simulating Circuits is brought much smaller.
Description of drawings
Fig. 1 is that employing 2 carrier radio frequencies of prior art close the transmitting chain theory diagram of road mode.
Fig. 2 is that the employing 2 carrier wave digital intermediate frequencies of prior art close the transmitting chain theory diagram of road mode.
Fig. 3 is that overloading of the present invention takes place frequently and penetrates numeral and close the road structure drawing of device.
Fig. 4 closes the road structure drawing of device as 2 carrier wave WCDMA signal baseband numerals of one embodiment of the invention.
Fig. 5 closes the road structure drawing of device as 3 carrier wave WCDMA signal baseband numerals of another embodiment of the present invention.
Fig. 6 is the frequency spectrum shift figure of N carrier wave base-band digital baseband signal when closing the road;
Fig. 7 is the frequency spectrum shift figure of N carrier radio frequency baseband signal when closing the road.
Embodiment
Below in conjunction with accompanying drawing device of the present invention is further described.
In fact, the present invention is different from existing radio frequency fully and closes the road mode; Also have technically than big difference with existing digital intermediate frequency mode, its main difference be, this device closes the road in base band and handles, output be baseband signal; And digital if technology to be intermediate frequency at numeric field close the road handles, output be modulated intermediate-freuqncy signal.Following mask body is that example is introduced with FPGA (Field Programmable Gate Array) device and realized that base-band digital closes the road device with 2 carrier wave WCDMA signals.
Shown in Figure 3 be the multicarrier emission numeral that the present invention constructs and close the road device, wherein not only comprised band pass filter same as the prior art, amplifier, linear power amplifier, local vibration source, comprised that also the peculiar base-band digital of the present invention closes road module, two identical D/A converters, I/Q modulator; The input base-band digital i/q signal In (n) of each carrier wave and Qn (n) input to base-band digital and close the road processing module and handle, in this module, carry out base-band digital and close dataway operation, the base-band digital I/Q of ECDC road output is I (n), Q (n), I (n), Q (n) are respectively through converting Simulation with I/Q signal to behind the D/A converter then, carry out I/Q through the I/Q modulator and be modulated to radio frequency, carry out filtering through band pass filter then, amplifier carries out delivering to linear power amplifier after the power amplification.The present invention handles by in baseband portion multicarrier base-band digital i/q signal being closed the road, synthetic 1 roadbed band numeral i/q signal; So, closing the road mode with radio frequency compares, the signal no matter device of the present invention is launched is single carrier or multicarrier, all only need 1 road signal processing link from the base band to the radio frequency, thereby brought very big simplification for the design of multicarrier transmitting chain, improve the reliability of system simultaneously, reduced the debugging work load of system greatly; In addition, closing the road mode with digital intermediate frequency compares, because the work clock speed of device of the present invention is lower, the D/A converter can adopt cheap low speed devices, close the road mode and must select at a high speed device for use and need not resemble digital intermediate frequency, and base band is closed the Digital Up Convert processing links of the high speed that the road mode need not be complicated.What base band closed that the road mode exports is baseband signal, and the device level of present analogue quadrature moducator has reached and baseband signal directly can be modulated to radio frequency output (promptly once simulating the up-conversion mode), this moment, local oscillation signal only needed one, compare with the Digital IF Processing mode, this mode gives the back pressure that the level Design of Simulating Circuits is brought much smaller.
In Fig. 4, I1 (n), Q1 (n) and I2 (n), Q2 (n) are respectively from the carrier wave 1 of base-band digital formed filter output and the i/q signal of carrier wave 2, and data rate is 15.36MSPS; I (n), Q (n) export baseband I/Q signal after closing the road, data rate is 15.36MSPS; CLK is the circuit working clock signal; This base-band digital device closes road (in the empty frame) and comprises a digital controlled oscillator NCO (Numeric Control Oscillator): NCO1, its vibration is output as sine and cosine signal: sin (ω in) and the cos (ω in) that frequency is ω i, here the NCO work clock is 15.36MHz, and ω in corresponds to 2.5MHz; Four digital multipliers: digital multiplier 1, digital multiplier 2, digital multiplier 3, digital multiplier 4; Four adders: adder 1, adder 2, adder 3, adder 4; Two subtracters: subtracter 1, subtracter 2.The relation of input and output is as follows:
I(n)=[I1(n)+I2(n)]cos(ωin)+[Q1(n)-Q2(n)]sin(ωin)(1)
Q(n)=[Q2(n)+Q1(n)]cos(ωin)+[I2(n)-I1(n)]sin(ωin)(2)
The process that is obtained I (n) by input I/Q is as follows: I1 (n) and I2 (n) are through adder 2 additions, and the cos of result and NCO1 (ω in) output multiplication obtains output [I1 (n)+I2 (n)] cos (ω in) component; Q1 (n) and Q2 (n) subtract each other through subtracter 1, output again with sin (ω in) output multiplication of NCO1, obtain [Q1 (n)-Q2 (n)] sin (ω in) component, two parts obtain I (n) output shown in final (1) by adder 3 additions.
The process that is obtained Q (n) by input I/Q is as follows: Q1 (n) and Q2 (n) are through adder 1 addition, and the cos of result and NCO1 (ω in) output multiplication is output as [Q2 (n)+Q1 (n)] cos (ω in) component; I2 (n) and I1 (n) subtract each other through subtracter 2, output again with sin (ω in) output multiplication of NCO1, obtain [Q1 (n)-Q2 (n)] sin (ω in) component, two parts obtain Q (n) output shown in final (2) by adder 4 additions.
This device major part is digital controlled oscillator NCO, and it mainly is made up of phase accumulator, sine lookup table, and the phase value of phase accumulator is that addition is carried out in stepping with phase-accumulated factor M under the effect of system works clock at every turn.The output phase value of phase accumulator is imported (if initial phase is set as the address of sine lookup table, then can the phase place initial value be set by initial phase input, the output phase and the phase place initial value sum of phase accumulator are imported as the address of sine lookup table), in sine lookup table, what deposited at this place, address is exactly the sine value of this phase value correspondence; So just finish the conversion of phase place and amplitude.By the sine wave that different phase-accumulated factor M and different sine lookup table numerical value can produce different frequency is set.Realize NCO easily with FPGA, can utilize the RAM of FPGA inside or ROM memory resource to deposit sine lookup table.
WCDMA base-band digital for 3 carrier waves closes the road processing, only the highest in 3 carrier waves and the 2 carrier wave base-band digital I/Q lowest frequency points correspondence need be closed the road algorithm by 2 carrier waves described above and handle (frequency of oscillation of NCO makes 5MHz into), the digital baseband I/Q that obtains 2 carrier waves closes road output, then that the digital baseband i/q signal of this 2 carrier wave is corresponding with intermediate frequency point carrier wave respectively again again base-band digital i/q signal is done addition, the digital baseband I/Q that can obtain 3 carrier waves closes road output, and specific implementation is seen Fig. 5 (in the empty frame).
Below this realization principle of closing the road device is described in detail, for convenience of description, implementation method with the synthetic 1 roadbed band numeral of N carrier wave WCDMA base-band digital i/q signal i/q signal is that example is described, and handles for the road of closing of other signal form, and method is derived equally like this.
Suppose that the N carrier signal is the base band after closing the road in base band to be closed the road signal directly be modulated to radio frequency with 1 I/Q modulator and obtain, then N carrier radio frequency modulation signal can be expressed as:
S(t)=I(t)cos(ωct)+Q(t)sin(ωct) (3)
I (t) and Q (t) close the I that exports behind the road for N carrier wave base-band digital, the Q analog signal; ω c is a carrier frequency, also is the local frequency of I/Q modulator radio-frequency (RF) local oscillator input port.Concrete frequency spectrum shift process such as Fig. 6.
Suppose that the N carrier signal is directly to use the I/Q modulators modulate behind radio frequency from base band respectively, close rood at radio frequency again and arrive that then the N carrier signal can be expressed as:
S (t)=S1 (t)+S2 (t)+...+SN-1 (t)+SN (t), work as N=2m, (m=1,2,3 ...) (4).
Frequency spectrum shift process such as Fig. 7.
S1(t)=I1(t)cos[(ωc-ωi)t]+Q1(t)sin[(ωc-ωi)t](5)
S2(t)=I2(t)cos[(ωc+ωi)t]+Q2(t)sin[(ωc+ωi)t](6)
Carrier wave N-1 signal:
S2m-1(t)=I2m-1(t)cos[(ωc-(2m-1)ωi)t]+Q2m-1(t)sin[(ωc-(2m-1)ωi)t] (7)
The carrier wave n-signal:
S2m(t)=I2m(t)cos[(ωc+(2m-1)ωi)t]+Q2m(t)sin[(ωc+(2m-1)ωi)t] (8)
S (t)=S1 (t)+S2 (t)+...+SN-1 (t)+SN (t), work as N=2m-1, (m=1,2,3 ...) (9)
S1(t)=I1(t)cos(ωct)+Q1(t)sin(ωct) (10)
......
Carrier wave N-1 signal:
S2m-1(t)=I2m-2(t)cos[(ωc-(2m-2)ωi)t]+Q2m-2(t)sin[(ωc-(2m-2)ωi)t] (11)
Carrier wave N:
S2m(t)=I2m-1(t)cos[(ωc+(2m-2)ωi)t]+Q2m-1(t)sin[(ωc+(2m-2)ωi)t] (12)
Here, ω i is half of 1 carrier wave WCDMA signal bandwidth.Because every carrier wave WCDMA signal bandwidth is 5MHz, so the frequency of ω i correspondence is 2.5MHz here, ω c is the centre frequency of multi-carrier signal; Its frequency spectrum shift process is seen Fig. 8; Wherein, IN (t) and QN (t) are the baseband I of carrier wave N, the Q analog signal;
When N=2m, (m=1,2,3 ...), (5) and (6), (7), (8) are launched to be respectively:
S1(t)=I1(t)cos(ωct)cos(ωit)-I1(t)sin(ωct)sin(ωit)+Q1(t)sin(ωct)cos(ωit)+Q1(t)cos(ωct)sin(ωit)
S2(t)=I2(t)cos(ωct)cos(ωit)+I2(t)sin(ωct)sin(ωit)+Q2(t)sin(ωct)cos(ωit)-Q2(t)cos(ωct)sin(ωit)
......
S2m-1(t)=I2m-1(t)cos(ωct)cos((2m-1)ωit)-I2m-1(t)sin(ωct)sin((2m-1)ωit)+Q2m-1(t)sin(ωct)cos((2m-1)ωit)+Q2m-1(t)cos(ωct)sin((2m-1)ωit)
S2m(t)=I2m(t)cos(ωct)cos((2m-1)ωit)+I2m(t)sin(ωct)sin((2m-1)ωit)+Q2m(t)sin(ωct)cos((2m-1)ωit)-Q2m(t)cos(ωct)sin((2m-1)ωit)
So have:
S(t)=S1(t)+S2(t)+......+S2m-1(t)+S2m(t)={[I1(t)+I2(t))cos(ωit)+...+[I2m-1(t)+I2m(t)]cos((2m-1)ωit)+[Q1(t)-Q2(t))sin(ωit)+...+[Q2m-1(t)-Q2m(t)]sin((2m-1)ωit))}cos(ωct)+{[Q2(t)+Q1(t))cos(ωit)+...+[Q2m(t)+Q2m-1(t)]cos((2m-1)ωit)+[I2(t)-I1(t))sin(ωit)+...+[I2m(t)-I2m-1(t)]sin((2m-1)ωit)))sin(ωct) (13)
Compare (3) and (13) formula,
I(t)=[I1(t)+I2(t)]cos(ωit)+...+[I2m-1(t)+I2m(t))cos((2m-1)ωit)+[Q1(t)-Q2(t)]sin(ωit)+...+[Q2m-1(t)-Q2m(t)]sin((2m-1)ωit) (14)
Q(t)=[Q2(t)+Q1(t)]cos(ωit)+...+[Q2m(t)+Qn-1(t)]cos((2m-1)ωit)+[I2(t)-I1(t)]sin(ωit)+...+[I2m(t)-I2m-1(t)]sin((2m-1)ωit) (15)
Numeric field can be expressed as:
I(n)=[I1(n)+I2(n)]cos(ωin)+...+[I2m-1(n)+I2m(n)]cos((2m-1)ωin)+[Q1(n)-Q2(n)]sin(ωin)+...+[Q2m-1(t)-Q2m(t)]sin((2m-1)ωit) (16)
Q(n)=[Q2(n)+Q1(n)]cos(ωin)+...+[Q2m(n)+Q2m-1(n)]cos((2m-1)ωin)+[I2(n)-I1(n)]sin(ωin)+...+[I2m(n)-I2m-1(n)]sin((2m-1)ωin) (17)
Formula (16), (17) are the algorithm expression formula that N (when N is even number) carrier wave base-band digital closes the road.
Such as, when N=2, be 2 carrier waves and close the road, have:
I(n)=[I1(n)+I2(n)]cos(ωin)+[Q1(n)-Q2(n)]sin(ωin)
(18)
Q(n)=[Q2(n)+Q1(n)]cos(ωin)+[I2(n)-I1(n)]sin(ωin)
(19)
The algorithm that this is realized just as shown in Figure 4.
Equally, when N=2m-1, (m=1,2,3 ...)
Can obtain following formula:
1, when N=2m-1=1, have:
I(n)=I1(n)
Q(n)=Q1(n)
2, when N=2m-1>1, have:
I(n)=I1(n)+[I2(n)+I3(n)]cos(2ωin)+...+[I2m-2(n)+I2m-1(n)]cos((2m-2)ωin)+[Q2(n)-Q3(n)]sin(2ωin)+...+[Q2m-2(t)-Q2m-1(t)]sin((2m-2)ωit) (20)
Q(n)=Q1(n)+[Q3(n)+Q2(n)]cos(2ωin)+...+[Q2m-2(n)+Q2m-1(n)]cos((2m-2)ωin)+[I3(n)-I2(n)]sin(2ωin)+...+[I2m-2(n)-I2m-1(n)]sin((2m-2)ωin) (21)
Formula (20), (21) are the algorithm expression formula that N (when N is odd number) carrier wave base-band digital closes the road.
Such as, when N=3, be 3 carrier waves and close the road, have:
I(n)=I1(n)+[I2(n)+I3(n)]cos(2ωin)+[Q2(n)-Q3(n)]sin(2ωin(22)
Q(n)=Q1(n)+[Q3(n)+Q2(n)]cos(2ωin)+[I3(n)-I2(n)]sin(2ωin)(23)
The method that this is realized just as shown in Figure 5.
So, when closing the road for even carriers, baseband portion must production (16) and (17) shown in I (n) and Q (n) close road output, when closing the road, export at I (n) shown in the essential production (20) of baseband portion and (21) and the road of closing of Q (n) for odd carriers.Then respectively through obtaining required Analog Baseband I/Q output signal after the D/A conversion.
Claims (7)
1, a kind of multicarrier emission numeral is closed the road device, comprises band pass filter, amplifier, linear power amplifier, local vibration source, it is characterized in that, comprises that also base-band digital closes road module, two identical D/A converters, I/Q modulator;
The input base-band digital i/q signal In (n) of each carrier wave and Qn (n) input to described base-band digital and close the road processing module and handle, in this module, carry out base-band digital and close dataway operation, the base-band digital I/Q of ECDC road output is I (n), Q (n), I (n), Q (n) are respectively through converting Simulation with I/Q signal to behind the D/A converter then, carry out I/Q through described I/Q modulator and be modulated to radio frequency, carry out filtering through described band pass filter then, described amplifier carries out delivering to described linear power amplifier after the power amplification.
2, multicarrier emission numeral according to claim 1 is closed the road device, it is characterized in that, close the road device for nd carrier emission numeral, described base-band digital closes the road module and comprises digital controlled oscillator, first digital multiplier, second digital multiplier, the 3rd digital multiplier, the 4th digital multiplier, first adder, second adder, the 3rd adder, the 4th adder, first subtracter and second subtracter;
I1 (n) and I2 (n) are through described second adder addition, and the cos of result and described digital controlled oscillator (ω in) output multiplication obtains output [I1 (n)+I2 (n)] cos (ω in) component; Q1 (n) and Q2 (n) subtract each other through described second subtracter, output again with sin (ω in) output multiplication of described digital controlled oscillator, obtain [Q1 (n)-Q2 (n)] sin (ω in) component, two parts obtain I (n) and export by described the 3rd adder addition;
Q1 (n) and Q2 (n) are through described first adder addition, and the cos of result and described digital controlled oscillator (ω in) output multiplication is output as [Q2 (n)+Q1 (n)] cos (ω in) component; I2 (n) and I1 (n) subtract each other through described second subtracter, output again with sin (ω in) output multiplication of described digital controlled oscillator, obtain [Q1 (n)-Q2 (n)] sin (ω in) component, two parts obtain Q (n) and export by described the 4th adder addition.
3, multicarrier emission numeral according to claim 2 is closed the road device, it is characterized in that, the vibration of described digital controlled oscillator is output as sine and cosine signal: sin (ω in) and the cos (ω in) that frequency is ω i, and its work clock is 15.36MHz, and ω in corresponds to 2.5MHz;
4, close the road device according to claim 2 or 3 described multicarrier emission numerals, it is characterized in that the relation of input and output is as follows: I (n)=[I1 (n)+I2 (n)] cos (ω in)+[Q1 (n)-Q2 (n)] sin (ω in); Q (n)=[Q2 (n)+Q1 (n)] cos (ω in)+[I2 (n)-I1 (n)] sin (ω in).
5, close the road device according to claim 2 or 3 described multicarrier emission numerals, it is characterized in that, described digital controlled oscillator comprises phase accumulator and sine lookup table, and the phase value of described phase accumulator is that addition is carried out in stepping with phase-accumulated factor M under the effect of system works clock at every turn; The output phase value of phase accumulator is as the address input of sine lookup table; The sine value of this phase value correspondence is deposited at the place, address in the described sine lookup table.
6, according to claim 1,2 or 3 described multicarrier emission numerals are closed the road device, it is characterized in that, close the road device for three carrier transmit numerals, this three carrier transmit numeral is closed in the device of road the highest and nd carrier base-band digital I/Q lowest frequency points correspondence closes the road device according to described nd carrier and handles, the digital baseband I/Q that obtains nd carrier closes road output, then that the digital baseband i/q signal of this nd carrier is corresponding with intermediate frequency point carrier wave respectively again again base-band digital i/q signal carries out addition through described the 3rd adder and the 4th adder respectively, and the digital baseband I/Q that can obtain three carrier waves closes road output.
7, close the road device according to claim 1,2 or 3 described multicarrier emission numerals, it is characterized in that, described digital controlled oscillator adopts scale programmable logic device to realize, utilizes the RAM of scale programmable logic device inside or ROM memory resource to deposit sine lookup table.
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| Application Number | Priority Date | Filing Date | Title |
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| CNB031359914A CN1275477C (en) | 2003-09-28 | 2003-09-28 | Multi-carrier transmssion digital merging device |
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| Application Number | Priority Date | Filing Date | Title |
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| CNB031359914A CN1275477C (en) | 2003-09-28 | 2003-09-28 | Multi-carrier transmssion digital merging device |
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| CN1529522A true CN1529522A (en) | 2004-09-15 |
| CN1275477C CN1275477C (en) | 2006-09-13 |
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Cited By (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102291365A (en) * | 2010-06-21 | 2011-12-21 | 中兴通讯股份有限公司 | Modulation and demodulation method and device based on in-phase/ quadrature (I/Q) modem |
| US8854989B2 (en) | 2010-01-20 | 2014-10-07 | Huawei Technologies Co., Ltd | Receiver, transmitter, feedback device, transceiver and signal processing method |
| CN107735954A (en) * | 2015-06-17 | 2018-02-23 | 华为技术有限公司 | Communication transmitters and method |
| CN111327353A (en) * | 2020-03-10 | 2020-06-23 | 航天恒星科技有限公司 | Radio frequency link supporting ultra-long distance transmission, design method and device and storage medium |
| CN111385056A (en) * | 2018-12-27 | 2020-07-07 | 中国电子科技集团公司第十五研究所 | Real-time stream processing method for effective load data |
| CN113194052A (en) * | 2021-04-01 | 2021-07-30 | 上海交通大学 | Reconfigurable radio frequency direct digital modulation communication system |
-
2003
- 2003-09-28 CN CNB031359914A patent/CN1275477C/en not_active Expired - Fee Related
Cited By (10)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US8854989B2 (en) | 2010-01-20 | 2014-10-07 | Huawei Technologies Co., Ltd | Receiver, transmitter, feedback device, transceiver and signal processing method |
| US9473338B2 (en) | 2010-01-20 | 2016-10-18 | Huawei Technologies Co., Ltd. | Receiver, transmitter, feedback device, transceiver and signal processing method |
| CN102291365A (en) * | 2010-06-21 | 2011-12-21 | 中兴通讯股份有限公司 | Modulation and demodulation method and device based on in-phase/ quadrature (I/Q) modem |
| WO2011160516A1 (en) * | 2010-06-21 | 2011-12-29 | 中兴通讯股份有限公司 | I/q modem based modulation-demodulation method and equipment |
| CN107735954A (en) * | 2015-06-17 | 2018-02-23 | 华为技术有限公司 | Communication transmitters and method |
| CN107735954B (en) * | 2015-06-17 | 2019-08-20 | 华为技术有限公司 | Communication transmitters and method |
| CN111385056A (en) * | 2018-12-27 | 2020-07-07 | 中国电子科技集团公司第十五研究所 | Real-time stream processing method for effective load data |
| CN111327353A (en) * | 2020-03-10 | 2020-06-23 | 航天恒星科技有限公司 | Radio frequency link supporting ultra-long distance transmission, design method and device and storage medium |
| CN111327353B (en) * | 2020-03-10 | 2022-04-08 | 航天恒星科技有限公司 | Radio frequency link supporting ultra-long distance transmission, design method and device and storage medium |
| CN113194052A (en) * | 2021-04-01 | 2021-07-30 | 上海交通大学 | Reconfigurable radio frequency direct digital modulation communication system |
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| CN1275477C (en) | 2006-09-13 |
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