WO2021093492A1 - 一种调制器、解调器以及无线通信系统 - Google Patents
一种调制器、解调器以及无线通信系统 Download PDFInfo
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- WO2021093492A1 WO2021093492A1 PCT/CN2020/120246 CN2020120246W WO2021093492A1 WO 2021093492 A1 WO2021093492 A1 WO 2021093492A1 CN 2020120246 W CN2020120246 W CN 2020120246W WO 2021093492 A1 WO2021093492 A1 WO 2021093492A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/10—Frequency-modulated carrier systems, i.e. using frequency-shift keying
- H04L27/103—Chirp modulation
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/69—Spread spectrum techniques
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L1/00—Arrangements for detecting or preventing errors in the information received
- H04L1/0001—Systems modifying transmission characteristics according to link quality, e.g. power backoff
- H04L1/0009—Systems modifying transmission characteristics according to link quality, e.g. power backoff by adapting the channel coding
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L1/00—Arrangements for detecting or preventing errors in the information received
- H04L1/004—Arrangements for detecting or preventing errors in the information received by using forward error control
- H04L1/0041—Arrangements at the transmitter end
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L1/00—Arrangements for detecting or preventing errors in the information received
- H04L1/004—Arrangements for detecting or preventing errors in the information received by using forward error control
- H04L1/0045—Arrangements at the receiver end
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/0014—Carrier regulation
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/18—Phase-modulated carrier systems, i.e. using phase-shift keying
- H04L27/20—Modulator circuits; Transmitter circuits
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/18—Phase-modulated carrier systems, i.e. using phase-shift keying
- H04L27/22—Demodulator circuits; Receiver circuits
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/69—Spread spectrum techniques
- H04B2001/6912—Spread spectrum techniques using chirp
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/0014—Carrier regulation
- H04L2027/0024—Carrier regulation at the receiver end
- H04L2027/0026—Correction of carrier offset
Definitions
- the present invention relates to the field of communication technology, in particular to a modulator, a demodulator and a wireless communication system.
- the binary or multi-ary modulation of the communication signal is realized by changing the amplitude, phase or frequency of the signal within the signal symbol period.
- AM amplitude modulation signal realizes amplitude modulation
- FM frequency modulation signal realizes Modulation of frequency.
- Chirp (chirp signal) modulation signal is a kind of spread spectrum modulation signal formed by monotonous changes in frequency with time according to a specific law for a period of time, which is a frequency modulation signal.
- Chirp technology was applied to communications in 1962. It expresses modulation information at different Chirp rates within the same symbol period.
- This technology is mainly used in sonar, radar, in order to be able to measure long-distance and retention time resolution, radar needs a short-term pulse wave but must continue to transmit the signal, and chirp can retain the continuous signal and the pulse at the same time. characteristic.
- radar positioning technology it can be used to increase the RF pulse width, increase the communication distance, and increase the average transmit power, while maintaining sufficient signal spectrum width without reducing the range resolution of the radar.
- the purpose of the embodiments of the present invention is to solve the problem of the phase ambiguity of the received signal, and realize the transmission modulation and reception demodulation of the multi-ary chirp signal.
- an embodiment of the present invention provides a modulator that sends a plurality of original rising chirp signals and original falling chirp signals before sending the target chirp signal for synchronizing the frequency and frequency of the chirp signal at the receiving demodulator.
- the modulator includes: The channel coding module is used for channel coding the data that needs to be sent; the multi-ary digital phase modulation module is used for modulating and mapping the data after the channel coding, and the corresponding phase data is obtained; the differential phase modulation module is used for The phase data is modulated into the initial phase; the chirp signal generating module generates a target chirp signal according to the initial phase.
- the modulator is further connected to a radio frequency module and a power amplifier module in sequence, and is suitable for outputting the target chirp signal to the radio frequency module and the power amplifier module.
- the frequency value range of the target chirp signal is related to the bandwidth of the transmitted signal.
- the time length of the target chirp signal is determined by the spreading factor of the target chirp signal.
- the present invention also provides a demodulator, including: being adapted to receive the target chirp signal transmitted via the above-mentioned modulator, and demodulate the target chirp signal;
- the demodulator includes : A chirp signal synchronization module for receiving the original rising chirp signal and the original falling chirp signal, and estimating the frequency deviation and the symbol deviation of the original rising chirp signal and the original falling chirp signal, It is used to realize the frequency deviation elimination and symbol synchronization of the target chirp signal;
- a parameter control module is used to provide the bandwidth and spreading factor of the target chirp signal;
- a local chirp generation module is suitable for according to the target chirp The bandwidth and spreading factor of the signal generate a local original down chirp signal, and a product signal is obtained according to the local original down chirp signal and the original rising chirp signal;
- an initial phase calculation module is used to perform a calculation on the product signal Accumulate and calculate the initial phase of the target chirp signal
- a residual fractional frequency offset elimination module which is used to eliminate the influence of frequency offset on phase demodulation.
- the residual fractional frequency offset elimination module includes: making the difference between the differentially decoded phase and the demapped result to obtain a phase deviation, and filtering and integrating the phase deviation to obtain a received solution
- the fractional frequency of the system is adjusted and fed back to the mixing module after passing through the chirp signal synchronization module.
- the present invention also provides a wireless communication system, including the modulator according to any one of the above and the demodulator according to any one of the above.
- the initial phase can be obtained, the problem of phase ambiguity can be solved, and the chirp signal can be modulated, transmitted, received and demodulated more accurately.
- Figure 1 is a schematic structural diagram of a wireless communication terminal in an embodiment of the invention.
- Figure 2 is the instantaneous frequency diagram of the original rising chirp signal
- Figure 3 is the instantaneous frequency diagram of the original down chirp signal
- Fig. 4 is a graph of simulation results comparing the transmission rate sensitivity performance of the demodulation system of the embodiment of the present invention and the traditional method.
- the modulator used in the embodiment of the present invention generates the target chirp signal, can obtain the initial phase, can solve the problem of phase ambiguity, and enables more precise modulation, transmission, reception and demodulation of the chirp signal.
- an embodiment of the present invention provides a wireless communication system, including a modulator 11 and a demodulator 12.
- the modulator 11 and the demodulator 12 are respectively described in detail below.
- the modulator 11 is adapted to generate a target chirp signal.
- the modulator 11 includes a channel coding module for channel coding the data to be sent.
- a multi-system digital phase modulation module (MPSK) is used for modulation and mapping of the channel-encoded data, and corresponding phase data is obtained.
- MPSK multi-system digital phase modulation module
- QDPSK Single Carrier Four Phase Differential Phase Shift Keying
- quaternary phase keying modulation is mapped, and 4PSK mapping is performed according to the input 2 bits. Get the corresponding phase data.
- the modulator further includes a differential phase modulation module for modulating the phase data into an initial phase.
- the phase data undergoes phase differential modulation processing to obtain the initial phase of each rising chirp signal. Specifically, first, the data to be sent is channel-encoded through the channel encoding module; the channel-encoded data is modulated and mapped, and the corresponding phase data is obtained; the phase data is modulated into the initial phase.
- Figure 2 is the original rising chirp signal
- Figure 3 is the original falling chirp signal.
- the chirp signal generation module generates a chirp signal according to the specified bandwidth BW and spreading factor SF.
- the chirp signal has a start frequency and a stop frequency, and linearly changes within the time range defined by the spreading factor.
- the chirp signal can be expressed for:
- a(t) is the envelope of the chirp signal
- f s is the carrier center frequency
- T is the duration of the chirp signal
- T 2 SF T s
- T s is the chirp signal sampling time.
- ⁇ is the slope of the chirp signal, which defines When ⁇ >0, the frequency linearly increases, which is a rising chirp signal; when ⁇ 0, the frequency linearly decreases, which is a falling chirp signal.
- ⁇ is the initial phase of the chirp signal.
- the modulator before the modulator sends the modulated chirp signal, it needs to send multiple original rising chirp signals and original falling chirp signals for realizing chirp signal frequency and symbol synchronization at the receiving demodulation end.
- the modulator is also coupled to a radio frequency module and a power amplifier module, respectively, and is suitable for outputting the target chirp signal to the radio frequency module and the power amplifier module.
- the chirp signal generation module outputs a baseband signal, and the I component and Q component of the baseband signal are partially converted into the desired transmission frequency by the radio frequency module, and amplified by the power amplifier (PA), and then transmitted by the antenna .
- PA power amplifier
- FIG. 1 a schematic structural diagram of a demodulator 12 in an embodiment of the present invention is given.
- the demodulator includes a chirp signal synchronization module, an initial phase calculation module, a differential phase demodulation module, an MPSK demapping module, a channel decoding module, a residual fractional frequency offset elimination module, and the like.
- a chirp signal synchronization module First, after the signal is received from the antenna, it is converted into a digital baseband signal by a low-noise amplifier (LNA), down-conversion module, analog-to-digital converter (ADC) and other modules, and then the baseband digital signal is processed by a digital baseband demodulator. Process and reconstruct the transmitted digital signal.
- LNA low-noise amplifier
- ADC analog-to-digital converter
- the chirp signal synchronization module estimates the frequency deviation and symbol deviation of the chirp signal according to the received multiple original rising chirp signals and the original falling chirp signal, so as to realize the frequency deviation elimination and symbol synchronization of the chirp signal. Then the local chirp signal generation module generates a local original falling chirp signal according to the signal bandwidth and spreading factor provided by the parameter control module, and multiplies the received modulated rising chirp signal to obtain a product signal. The initial phase calculation module accumulates the multiplied product signal within the symbol time range of the chirp signal, and then sends the calculated and accumulated baseband signal I component and Q component results to the phase calculation unit to estimate the phase of the baseband signal, That is, the initial phase of the chirp signal is received.
- the differential phase demodulation module performs differential decoding on the estimated initial phase of the chirp signal.
- the MPSK demapping module then performs demapping according to MPSK.
- the residual fractional frequency offset elimination module makes the difference between the differential phase and the de-mapping decision result to obtain the phase deviation, which is filtered and integrated to obtain the fractional frequency of the receiving demodulation system, thereby eliminating the residual fractional frequency deviation for the phase solution The impact of tune.
- the data obtained after the final demapping passes through the channel decoding module, and the transmitted data modulated by the transmitting end can be reconstructed.
- Fig. 4 is a simulation of the relationship between the transmission rate and the signal-to-noise ratio of the chirp modulation system and the traditional chirp modulation system in an embodiment of the simulated invention. It can be seen that under the same transmission rate, the performance of the chirp modulation system of QDPSK is better than that of the traditional chirp modulation system, which proves the effectiveness of this embodiment.
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Abstract
本发明实施例提供一种调制器,包括:信道编码模块,用于对需要发送的数据进行信道编码;多进制数字相位调制模块,用于所述信道编码后的数据进行调制映射,且得到对应的相位数据;差分相位调制模块,用于将所述相位数据调制成初始相位;线性调频信号生成模块,根据所述初始相位生成目标线性调频信号。采用上述调制器生成目标线性调频信号,可以获得初始相位,可以解决相位模糊的问题,使得更加精准的调制传输和接收解调线性调频信号。
Description
本发明涉及通信技术领域,尤其涉及一种调制器、解调器以及无线通信系统。
在数字通信系统中,通过在信号码元周期内改变信号的幅度、相位或频率来实现对通信信号的二进制或者多进制调制,AM调幅信号是实现对幅度的调制,而FM调频信号是实现对频率的调制。Chirp(线性调频信号)调制信号是一段持续时间内频率随时间按特定规律做单调变化而形成的一种扩频调制信号,属于频率调制信号。
线性调频技术于1962年被应用到通信中,它以同一码元周期内不同的Chirp速率表达调制信息。该项技术主要应用于声纳,雷达中,为了能够测量长距离又保留时间的分辨率,雷达需要短时间的脉冲波但是又要持续的发射信号,而线性调频可以同时保留连续信号和脉冲的特性。在雷达定位技术中,它可用来增大射频脉冲宽度、加大通信距离、提高平均发射功率,同时又保持足够的信号频谱宽度,不降低雷达的距离分辨率。
目前的多进制的线性调频键控调制方法中由于接收信号的载波初始相位未知,导致接收信号相位模糊,无法估计实际发射信号的初始相位,因此无法判断发送的多进制调制数据。
发明内容
本发明实施例的目的实在解决了接收信号相位模糊的问题,实现 了多进制线性调频信号的传输调制和接收解调。
为实施上述目的,本发明实施例提供一种调制器,在发送目标线性调频信号之前发送多个原始上升线性调频信号和原始下降线性调频信号,用于同步接收解调器端线性调频信号频率及符号,其中,所述目标线性调频信号的斜率大于0时,所述目标线性调频信号为上升线性调频信号,所述目标线性调频信号的斜率小于0时,所述目标线性调频信号为下降线性调频信号;初始相位为0的所述上升线性调频信号为所述原始上升线性调频信号,所述初始相位为0的所述下降线性调频信号为所述原始下降线性调频信号;所述调制器包括:信道编码模块,用于对需要发送的数据进行信道编码;多进制数字相位调制模块,用于所述信道编码后的数据进行调制映射,且得到对应的相位数据;差分相位调制模块,用于将所述相位数据调制成所述初始相位;线性调频信号生成模块,根据所述初始相位生成目标线性调频信号。
可选的,所述调制器还与射频模块及功率放大模块依次连接,适于将所述目标线性调频信号输出至所述射频模块及所述功率放大模块。
可选的,所述目标线性调频信号的频率取值范围与发射信号的带宽相关。
可选的,所述目标线性调频信号的时间长度由所述目标线性调频信号的扩频因子确定。
相应的,本发明还提供一种解调器,包括:适于接收经由以上所述的调制器发射的目标线性调频信号,并对所述目标线性调频信号进 行解调;所述解调器包括:线性调频信号同步模块,用于接收所述原始上升线性调频信号和所述原始下降线性调频信号,并估计所述原始上升线性调频信号和所述原始下降线性调频信号的频率偏差和符号偏差,用于实现所述目标线性调频信号频率偏差消除和符号同步;参数控制模块,用于提供所述目标线性调频信号的带宽及扩频因子;本地线性调频生成模块,适于根据所述目标线性调频信号的带宽及扩频因子生成本地原始下降线性调频信号,且根据所述本地原始下降线性调频信号与所述原始上升线性调频信号获得乘积信号;初始相位计算模块,用于对所述乘积信号进行累加,并计算出所述目标线性调频信号的初始相位;差分相位解调模块,用于对所述目标线性调频信号的初始相位进行差分解码;多进制数字相位解调模块,用于对所述差分解码后的初始相位进行解映射;信道解码模块,用于重建所述目标线性调频信号。
可选的,还包括:残余小数频偏消除模块,用于消除频率偏差对相位解调的影响。
可选的,所述残余小数频偏消除模块包括:将所述差分解码后的相位和所述解映射后的结果做差值,得到相位偏差,对所述相位偏差进行滤波积分,得到接收解调系统的小数频率,并通过所述线性调频信号同步模块之后反馈回混频模块。
相应的,本发明还提供一种无线通信系统,包括如上任一项所述的调制器以及如上任一项所述的解调器。
与现有技术相比,本发明实施例的技术方案具有以下有益效果:
采用上述调制器生成目标线性调频信号,可以获得初始相位,可以解决相位模糊的问题,使得更加精准的调制传输和接收解调线性调频信号。
图1是发明实施例中的一种无线通信终端的结构示意图;
图2是原始上升线性调频信号的瞬时频率图;
图3是原始下降线性调频信号的瞬时频率图;
图4本发明实施例的解调系统和传统方式传输速率灵敏度性能比较仿真结果图。
现有相关技术中的多进制的线性调频键控调制方法,由于接收信号的载波初始相位未知,导致接收信号相位模糊,无法估计实际发射信号的初始相位,因此无法判断发送的多进制调制数据。
本发明实施例采用的调制器生成目标线性调频信号,可以获得初始相位,可以解决相位模糊的问题,使得更加精准的调制传输和接收解调线性调频信号。
为使本发明的上述目的、特征和有益效果能够更为明显易懂,下面结合附图对本发明的具体实施例做详细的说明。
参照图1,本发明实施例提供了一种无线通信系统,包括调制器11以及解调器12。下面分别对调制器11和解调器12进行详细说明。
在具体实施例中,所述调制器11适于生成目标线性调频信号。在本实施例中,所述调制器11包括信道编码模块,用于对需要发送 的数据进行信道编码。多进制数字相位调制模块(MPSK),用于所述信道编码后的数据进行调制映射,且得到对应的相位数据。
在本实施例中,如下表所示,采用QDPSK(单载波四相差分相移键控)调制,对数据比特进行2bit分组,四进制相位键控调制映射,根据输入的2bit进行4PSK映射,得到对应的相位数据。
b(2k-1) | b(2k) | φ(k) |
0 | 0 | π/4 |
0 | 1 | 3π/4 |
1 | 0 | -π/4 |
1 | 1 | -3π/4 |
本实施例中,所述调制器还包括差分相位调制模块,用于将所述相位数据调制成初始相位。
相位数据经过相位差分调制处理得到每个上升线性调频信号的初始相位。具体的,首先将需要发送的数据经过信道编码模块进行信道编码;将信道编码后的数据进行调制映射,且得到对应的相位数据;将相位数据调制成初始相位。
相位数据线性调频信号生成模块根据初始相位信息、斜率信息等生成调制线性调频信号。这里定义初始相位φ=0,μ>0时为原始上升线性调频信号,μ<0时为原始下降线性调频信号。图2是原始上升线性调频信号,图3是原始下降线性调频信号。
线性调频信号生成模块根据指定的带宽BW和扩频因子SF生成线性调频信号,线性调频信号具有起始频率和终止频率,并在由扩频因 子定义的时间范围内线性变化,线性调频信号可表示为:
这里,a(t)是线性调频信号的包络,f
s是载波中心频率,T是线性调频信号持续时间,T=2
SFT
s,T
s是线性调频信号采样时间。μ是线性调频信号的斜率,定义
当μ>0时,频率线性递增,为上升线性调频信号,当μ<0时,频率线性递减,为下降线性调频信号。φ为线性调频信号的初始相位。
本实施例中,调制器在发送调制线性调频信号前,需要发送多个原始上升线性调频信号和原始下降线性调频信号用于在接收解调端实现线性调频信号频率及符号同步。
所述调制器还分别与射频模块及功率放大模块耦接,适于将所述目标线性调频信号输出至所述射频模块及所述功率放大模块。在本实施例中,线性调频信号生成模块输出基带信号,该基带信号的I分量和Q分量由射频模块部分转化为期望的传输频率,并由功率放大器(PA)进行放大,再由天线进行发射。
继续参照图1,给出了本发明实施例中的一种解调器12的结构示意图。
所述解调器包括线性调频信号同步模块、初始相位计算模块、差分相位解调模块、MPSK解映射模块、信道解码模块、残余小数频偏消除模块等。首先信号从天线中接收下来后,经过低噪声放大器(LNA)、下变频模块、模拟数字转化器(ADC)等模块转成数字基带信号,接 下来由数字基带解调器对该基带数字信号进行处理,重建发送的数字信号。线性调频信号同步模块根据接收到的多个原始上升线性调频信号和原始下降线性调频信号估计线性调频信号的频率偏差和符号偏差,从而实现线性调频信号频率偏差消除和符号同步。然后本地线性调频信号生成模块根据参数控制模块提供的信号带宽及扩频因子等生成本地原始下降线性调频信号,与将接收到的调制的上升线性调频信号进行相乘,获得乘积信号。初始相位计算模块并对相乘后的乘积信号在线性调频信号符号时间范围内进行累加,其后将计算累加得到的基带信号I分量和Q分量结果送入相位计算单元,估计基带信号的相位,即接收到线性调频信号的初始相位。差分相位解调模块对估计出的线性调频信号初始相位进行差分解码。MPSK解映射模块再根据MPSK进行解映射。残余小数频偏消除模块将差分相位和解映射后的判决结果做差值,得到相位偏差,对该偏差进行滤波积分,可得到接收解调系统的小数频率,从而消除残余的小数频率偏差对相位解调的影响。另外,最后解映射后得到的数据经过信道解码模块,可以重建出发射端调制的发送数据。
图4是仿真发明实施例中的线性调频调制系统与传统线性调频调制系统的传输速率与信噪比关系。可见,在相同传输速率情况下,QDPSK的线性调频调制系统性能优于传统线性调频调制系统,证明本实施例的有效性。
虽然本发明披露如上,但本发明并非限定于此。任何本领域技术人员,在不脱离本发明的精神和范围内,均可作各种更动与修改,因 此本发明的保护范围应当以权利要求所限定的范围为准。
Claims (8)
- 一种调制器,其特征在于,在发送目标线性调频信号之前发送多个原始上升线性调频信号和原始下降线性调频信号,用于同步接收解调器端线性调频信号频率及符号,其中,所述目标线性调频信号的斜率大于0时,所述目标线性调频信号为上升线性调频信号,所述目标线性调频信号的斜率小于0时,所述目标线性调频信号为下降线性调频信号;初始相位为0的所述上升线性调频信号为所述原始上升线性调频信号,所述初始相位为0的所述下降线性调频信号为所述原始下降线性调频信号;所述调制器包括:信道编码模块,用于对需要发送的数据进行信道编码;多进制数字相位调制模块,用于所述信道编码后的数据进行调制映射,且得到对应的相位数据;差分相位调制模块,用于将所述相位数据调制成所述初始相位;线性调频信号生成模块,根据所述初始相位生成目标线性调频信号。
- 如权利要求1所述的调制器,其特征在于,所述调制器还与射频模块及功率放大模块依次连接,适于将所述目标线性调频信号输出至所述射频模块及所述功率放大模块。
- 如权利要求1所述的调制器,其特征在于,所述目标线性调频信号的频率取值范围与发射信号的带宽相关。
- 如权利要求1所述的调制器,其特征在于,所述目标线性调频信 号的时间长度由所述目标线性调频信号的扩频因子确定。
- 一种解调器,其特征在于,包括:适于接收经由权利要求1-4任一项所述的调制器发射的目标线性调频信号,并对所述目标线性调频信号进行解调;所述解调器包括:线性调频信号同步模块,用于接收所述原始上升线性调频信号和所述原始下降线性调频信号,并估计所述原始上升线性调频信号和所述原始下降线性调频信号的频率偏差和符号偏差,用于实现所述目标线性调频信号频率偏差消除和符号同步;参数控制模块,用于提供所述目标线性调频信号的带宽及扩频因子;本地线性调频生成模块,适于根据所述目标线性调频信号的带宽及扩频因子生成本地原始下降线性调频信号,且根据所述本地原始下降线性调频信号与所述原始上升线性调频信号获得乘积信号;初始相位计算模块,用于对所述乘积信号进行累加,并计算出所述目标线性调频信号的初始相位;差分相位解调模块,用于对所述目标线性调频信号的初始相位进行差分解码;多进制数字相位解调模块,用于对所述差分解码后的初始相位进行解映射;信道解码模块,用于重建所述目标线性调频信号。
- 如权利要求5所述的解调器,其特征在于,还包括:残余小数频偏消除模块,用于消除频率偏差对相位解调的影响。
- 如权利要求5所述的解调器,其特征在于,所述残余小数频偏消除模块包括:将所述差分解码后的相位和所述解映射后的结果做差值,得到相位偏差,对所述相位偏差进行滤波积分,得到接收解调系统的小数频率,并通过所述线性调频信号同步模块之后反馈回混频模块。
- 一种无线通信系统,其特征在于,包括如权利要求1-4任一项所述的调制器以及如权利要求5-7任一项所述的解调器。
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