1. Technical Field
Embodiments of the present disclosure relate generally to communication circuits, and more specifically to pulse shaping in a communication system.
2. Related Art
Communication systems are well-known in the relevant arts, and generally include one or more transmitters and one or more receivers. The transmitters and receivers may communicate with each other using corresponding modulation techniques (digital and/or analog) and protocols. The modulation techniques include those in which information is represented as changes in one or more of the amplitude, frequency and phase of a carrier signal used in a transmitter, as is also well-known in the relevant arts. Some examples of modulation techniques used in communication systems include frequency-shift keying (FSK), phase-shift keying (PSK), quadrature-amplitude modulation (QAM), etc.
Pulse shaping generally refers to a technique by which the shape of a signal (e.g., binary pulse or a baseband signal) to be transmitted is modified (or filtered) prior to transmission. Pulse shaping may be used in a communication system for reasons such as to limit the bandwidth of a signal to fit within a channel bandwidth allocated or available for use by the signal, to mitigate the undesirable effects of inter-symbol interference due to finite bandwidth of the communication channel used (wireless or wireline), etc. Pulse shaping may also be used in a receiver, in conjunction with pulse shaping in a corresponding transmitter, to enable matched filtering of a received signal to minimize, or reduce to zero, noise due to inter-symbol interference (ISI).
The specific pulse shapes (or pulse shaping filters) that may be used in a transmitter and receiver of a communication system may be selected based on considerations such as, for example, ease of implementation, the desired level of reduction in ISI, etc.
This Summary is provided to comply with 37 C.F.R. §1.73, requiring a summary of the invention briefly indicating the nature and substance of the invention. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.
A transmitter includes a constellation mapper, a transmit pulse shaper and a power amplifier. The constellation mapper is coupled to receive a plurality of data sets, and to generate corresponding symbol values representing each data set in the plurality of data sets. The transmit pulse shaping filter is coupled to receive and to filter the symbol values to generate corresponding pulse-shaped values, and is implemented as a raised cosine pulse filter. The power amplifier is coupled to receive and to amplify the pulse-shaped signals to generate an amplified signal. The amplified signal is coupled to be transmitted on a communications channel.
Several embodiments of the present disclosure are described below with reference to examples for illustration. It should be understood that numerous specific details, relationships, and methods are set forth to provide a full understanding of the embodiments. One skilled in the relevant art, however, will readily recognize that the techniques can be practiced without one or more of the specific details, or with other methods, etc.
The drawing in which an element first appears is indicated by the leftmost digit(s) in the corresponding reference number.
Various embodiments are described below with several examples for illustration.
1. Example Environment
Transmitter 190 is shown containing constellation mapper 105, transmit pulse shaping filter 110, digital to analog converter (DAC) 115, analog filter 120, up-converter 125, power amplifier 130 and antenna 140.
Constellation mapper 105 receives binary data on path 101. The binary data on path 101 represent information sought to be transmitted by transmitter 190, and may be generated by a processor or a host device, not shown. However, such a processor or host device may also be contained within transmitter 190. Constellation mapper 105 selects groups (plurality of data sets) of successive bits from the binary data received on path 101, and assigns a symbol value according to a desired type of PSK to each group, i.e., the mapping between a data set and the corresponding symbol value is according to PSK modulation. The size of each group, i.e., the number of bits in each group of successive bits, depends on the specific type of PSK used in transmitter 190 (and communication system 100 in general). For example, if binary phase shift keying (BPSK) is used, the size equals one bit. If quadrature phase shift keying (QPSK) is used, the size equals two bits. For other types of PSK such as quadrature amplitude modulation (QAM), the size may be correspondingly different. The operation performed by constellation mapper 105 in selecting symbol values corresponding to each group of successive data bits represents a digital modulation operation.
Symbol values selected by constellation mapper 105 may, in general, be represented mathematically by complex numbers. Constellation mapper 105 forwards the ‘real’ component of a complex number representing a symbol value on path 107Re, and the ‘imaginary’ component of the complex number representing the symbol value on path on path 107Im.
Transmit pulse shaping filter 110 receives, on respective paths 107Re and 107Im, the real and imaginary components of each complex value generated by constellation mapper 105. Transmit pulse shaping filter 110 filters each of the values received on path 107Re and 107Im according to a desired pulse shape. The desired pulse shape may be designed to satisfy one or more requirements. The requirements may include reduction of the bandwidth occupied by a signal transmitted by transmitted 190, minimization of ISI in a receiver that receives and decodes the transmissions of transmitter 190, reduction in the peak-to-average ratio (PAR) of the output of power amplifier 130 for transmitting signals, etc. In an embodiment, transmit pulse shaping filter 110 is implemented as a finite impulse response (FIR) filter whose impulse response (values of filter coefficients) is the desired pulse shape. Thus, transmit pulse shaping filter 110 filters each of the values received on paths 107Re and 107Im to generate corresponding pairs of ‘pulse-shaped’ digital signals. Transmit pulse shaping filter 110 forwards each pair of pulse-shaped digital signals on path 112.
DAC 115 receives each of the pairs of pulse-shaped digital signals on path 112, and generates, on path 117, corresponding analog signals (in the form of voltage or current) representing the digital values. Thus, DAC 115 generates, in each symbol duration, analog representations of the real and imaginary components of the complex symbol value generated by constellation mapper 105. DAC 115 forwards the analog signals on path 117.
Analog filter 120 operates as a reconstruction filter, and performs low-pass filtering of the analog signals forwarded on path 117 by DAC 115, to generate corresponding filtered analog signals with frequency components restricted to lie within a desired bandwidth. Thus, analog filter 120 filters the analog representations of the real and imaginary components of each symbol value generated by constellation mapper 105. Analog filter 120 provides the low-pass filtered analog signals on path 122.
In
Up-converter 125 receives a local oscillator (LO) signal on path 126, and generates a ninety-degree phase-shifted LO signal internally. The pair of LO signals, thus obtained represent sine and cosine LO signals. Alternatively, up-converter 125 may directly receive the sine and cosine LO signals. The LO signal on path 166 may be generated by an oscillator, not shown, but contained in receiver 195. Up-converter 125 mixes (multiplies) the real component received on path 122 with the cosine LO signal, and the imaginary component received on path 122 with the sine LO signal. Up-converter 125 combines, by addition, the respective products of the mixing operations noted above. The sum, thus, obtained, represents an up-converted signal. The products of the mixing operation may be filtered by a filter (not shown, but assumed to be contained within up-converter 125) to remove undesired products generated by the mixing operation, and to provide, on path 127, only the desired frequency band of the up-converted signal. In effect, up-converter 125 increases the carrier frequency of the signal received on path 122 to a value in a desired (or usable/allowed) transmit frequency band, and the signal on path 127 may be viewed as an up-converted transmit signal.
Power amplifier 130 amplifies the up-converted transmit signal received on path 127, and generates a power-amplified signal (amplified signal) on path 132. Antenna 140 transmits the amplified signal on a wireless medium.
Constellation mapper 105, DAC 115, analog filter 120, up-converter 125, power amplifier 130 and antenna 140 may be implemented in a known way.
Receiver 195 is shown containing antenna 150, low-noise amplifier (LNA) 160, down-converter 165, analog to digital converter (ADC) 170, receive pulse shaping filter 175, and baseband processor 180.
Antenna 150 receives a PSK modulated signal from a wireless medium, and provides the signal to LNA 160 via path 157. The signal received by antenna 150 may correspond, for example, to the signal transmitted by antenna 140 of transmitter 190. While transmitter 190 and receiver 195 are described as communicating over a wireless medium, in other embodiments a wireline medium may instead be used. The medium over which signals are transmitted by transmitter 190 (and received by receiver 195) is referred to herein as a communication medium, and includes both wired and wireless transmission paths.
LNA 160 amplifies the signal received on path 157 with minimal addition of noise, and provides an amplified signal on path 162. Down-converter 165 mixes signal 162 with a local oscillator signal received on path 166 to generate a down-converted signal at a lower carrier frequency. The products of mixing generated in down-converter 165 may be low-pass filtered by one or more filters contained in down-converter 165 to remove undesired sidebands of mixing. Down-converter 165 provides the down-converted signal on path 167. In an embodiment, down-converter 165 employs IQ demodulation. Accordingly, down-converter 165 mixes signal 162 with sine and cosine local oscillator (LO) signals to generate in-phase (I) and quadrature phase (Q) products, as is well-known in the relevant arts. The I and Q products are low-pass filtered, and each of the low-pass filtered products is provided to ADC 170 via corresponding paths assumed to be contained in path 167.
ADC 170 converts the filtered I and Q products received on path 167 to corresponding digital codes. ADC 170 provides the digital codes on path 172. Receive pulse shaping filter 175 filters the digital codes corresponding to the I and Q signal components received on path 172 according to a desired pulse shape. In an embodiment, receive pulse shaping filter 175 is implemented as an FIR filter. The specific implementation of receive pulse shaping filter 175 may be designed to minimize ISI (in conjunction with operation of a transmit pulse shaping filter in a corresponding transmitter), as is well-known in the relevant arts. Receive pulse shaping filter 175 provides the pulse-shaped I and Q signal components on path 177. The pulse-shaped I and Q components represent a baseband signal. While only one instance of each of ADC 170, and receive pulse shaping filter 175 is shown in
Baseband processor 180 samples the I and Q signal components received on path 177 at appropriate sampling instances (which typically correspond to instances at which the SNR (signal-to-noise ratio) of the sampled signal is a maximum). Baseband processor 180 extracts, by demodulation, the data or symbol values contained in signal 177. Baseband processor 180 may either operate on the data thus extracted to provide desired features, or forward the data on path 185 to a processing device (not shown). LNA 160, down-converter 165, ADC 170 and baseband processor 180 may be implemented in a known way.
Typically, transmit pulse shaping filter 110 is implemented as a root raised cosine filter (RRC filter, also known as square-root raised cosine filter), with a desired roll-off factor and length. Complementarily, receive pulse shaping filter 175 is also implemented as a RRC filter. As is well-known in the relevant arts, the combination of a RRC filter implemented as transmit pulse shaping filter 110 in transmitter 190, and a RRC filter implemented as receive pulse shaping filter in receiver 195 enables communicating system 100 (and receiver 195 in particular) to operate with matched filtering. As is also well-known in the relevant arts, such matched filtering enables optimal operation of communication system 100 (enabling a correct determination in receiver 195 of data transported in a transmitted signal) in the presence of noise in the wireless medium (communication channel).
However, one drawback with implementing transmit pulse shaping filter 110 may be that the peak-to-average ratio (PAR, also known as crest factor or peak-to-average power ratio) of output 132 of power amplifier 130 may be unacceptably high, as illustrated with respect to the example waveform of
Table 250 of
A need to support a high PAR value of signal 132 may require that power amplifier 130 be implemented to have adequately linear amplification (or gain) characteristics, which in turn may translate to lower power efficiency of power amplifier 130. Such lower power efficiency may be unacceptable at least in some deployment environments. For example, when transmitter 190 is part of a medical implant operating on battery power, it may be desirable to maximize power efficiency of power amplifier 130, while still providing some level of transmit pulse shaping to ensure that out-of band transmissions of transmitter 190 are within acceptable or allowed levels.
2. Transmit Pulse Shaping Filter for PAR Reduction
In an embodiment, transmit pulse shaping filter 110 is implemented as a raised cosine filter.
As is well-known in the relevant arts, the impulse response h(t) of a raised cosine filter is specified by equation 1 below:
h(t)=[(sinc(t/T))(cos(απt/T))/(1−((2αt/T)2)] Equation 1
wherein,
sinc( ) represents the sinc function,
T represents the period of a symbol, and
α represents a roll-off factor of the raised cosine filter.
wherein,
sin( ) represents a sine function, and
ω represents frequency.
In an embodiment, transmit pulse shaping filter 110 is implemented as a raised cosine filter with a length of two symbols on either side of the peak (i.e., total of 4 symbols). Referring to
In an embodiment, transmit pulse shaping filter 110, implemented as a raised cosine filter, is used in conjunction with π/2-shift BPSK modulation (implemented in constellation mapper 105). When π/2-shift BPSK modulation is used, phase transitions (of the π/2-shift BPSK modulated signal) are limited to ninety degrees (as against 180 degrees for normal BPSK).
Due to the lower value of phase shift in π/2-shift BPSK modulation, the PAR of signal 132 is further reduced. Table 500 of
Thus, the use of raised cosine filtering for pulse shaping, in combination with π/2-shift BPSK modulation, implemented in transmitter 190 reduces the PAR of signal 132. Therefore, power amplifier 130 may be implemented to have a relatively non-linear gain characteristic. Thus, power amplifier 130 may be implemented as a class B, class C or class D power amplifier, and therefore with greater power efficiency than otherwise (for example, a class A amplifier).
Complementary to the implementation of transmit pulse shaping filter 110 as a raised cosine filter, receive pulse shaping filter 175 of receiver 195 is implemented as a root-raised cosine filter (RRC filter). As is well-known in the relevant arts, a root-raised cosine filter is defined by a frequency response that is the square root of the frequency response of a raised cosine filter, and therefore equals √H(ω), wherein √ represents a square root operator, and H(ω) is as defined above in Equation 2. The specific impulse response (or frequency response) of an RRC filter is also determined by a corresponding roll-off factor, as is well-known in the relevant arts.
While, the use of a root-raised cosine filter in receiver 195 in conjunction with a raised cosine filter in transmitter 190 may not lend to reduction of ISI to zero in receiver 195, the RRC filter characteristics may be selected to minimize ISI, as well as implementation complexity. In an embodiment, receive pulse shaping filter 175 is implemented as an RRC filter of one-sided length of two symbol periods (i.e., a total of four symbol periods).
A desired signal-to-interference ratio (SIR) may be obtained by using a suitable combination of roll-off factor and symbol rate parameter (1/T) for the RRC filter in receiver 195.
In an embodiment, transmit pulse shaping filter 110 is implemented as a raised cosine filter with pulse length of 2 on either side of the peak response (i.e., a total of 4 symbol periods), and a roll-off factor α of 0.5, corresponding to a PAR of signal 132 of 0.76 dB and adjacent channel emissions below −36 dB (as also shown in row 2 of table 500). In the embodiment, receive pulse shaping filter 175 is implemented as a RRC filter with a roll-off factor of 0.2 and a symbol rate parameter (1/T) of 250 KHz. The corresponding value of ISI is −40 dB and SNR degradation is less than 0.5 dB. Transmit power back-off when using raised cosine transmit pulse shaping with pulse length of a total of 4 symbol periods and roll-off factor α of 5 is 0.76 dB due to PAR of 0.76 dB (as shown in row 510 of
In another embodiment, transmit pulse shaping filter 110 is implemented as a raised cosine filter with pulse length pulse of 2 on either side of the peak response and a roll-off factor α of 0.5, and receive pulse shaping filter 175 is implemented as a RRC filter with a roll-off factor of 0, and symbol rate parameter (1/T) of 240 KHz. The corresponding value of ISI is −25 dB and SNR degradation is less than 0.2 dB. Overall link budget improves by approximately by 0.94 dB [(1.9−0.76)−0.2].
In general, when higher values of SIR are desired (as, for example, when using higher constellations), receive pulse shaping filter 175 may be implemented as a RRC filter with a roll-off factor of 0.2 and a symbol rate parameter (1/T) of 250 KHz. When relatively lower values of SIR are acceptable (as, for example, when using lower constellations), receive pulse shaping filter 175 is implemented as a RRC filter with a roll-off factor of 0, and symbol rate parameter (1/T) of 240 KHz, as such an approach provides better link budget improvement.
Transmit pulse shaping filter 110 and receive pulse shaping filter 175 may each be implemented using hardware components, by the execution of instructions in a processor, or a combination of the two.
In the illustration of
While various embodiments of the present disclosure have been described above, it should be understood that they have been presented by way of example only, and not limitation. Thus, the breadth and scope of the present disclosure should not be limited by any of the above-described embodiments, but should be defined only in accordance with the following claims and their equivalents.
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Number | Date | Country | |
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20120163489 A1 | Jun 2012 | US |