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Claims  |
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What is claimed is:
1. A multiband MIMO-based dual-mode portable communication system has P Wideband Code Division Multiple Access (W-CDMA) and Ultra Wideband (UWB) portable stations having N
antennas, a Multiple-Input Multiple-Output (MIMO)-based UWB base station having M antennas, a MIMO-based W-CDMA base station having Q antennas, an UWB multiband, a W-CDMA frequency band, and MIMO channels, where M, N, P, Q, and R are integers and greater
than 1, the communication system further comprising: said MIMO-based W-CDMA base station including a W-CDMA baseband processor unit coupled to a MIMO-based W-CDMA filtering and multicarrier radio frequency (RF) unit that is connected to a W-CDMA control
processor unit, which is connected with the W-CDMA baseband processor unit; said MIMO-based W-CDMA filtering and multicarrier RF unit coupled to the Q antennas; said W-CDMA baseband processor unit further including two digital filters, two down
samplings, a MUX, and a multiband rake receiver and decoder unit; said MIMO-based UWB base station including an UWB baseband processor unit coupled to a MIMO-based UWB spreading and filtering unit followed by a MIMO-based modulation multicarrier unit
that is connected to an UWB control processor unit, which is also connected with the UWB baseband processor unit and the MIMO-based spreading and filtering unit; said MIMO-based modulation multicarrier unit coupled to the M antennas; each of said P
W-CDMA and UWB portable stations including a MIMO-based dual-mode W-CDMA and UWB filtering and multicarrier unit, a W-CDMA mobile baseband processor unit, an UWB OFDM multiband baseband processor unit, a W-CDMA and UWB OFDM multiband control processor
unit, and a sharing memory bank unit; said MIMO-based dual-mode W-CDMA and UWB filtering and multicarrier unit further including two low noise amplifiers followed by two automatic gain controllers coupled to two analog bandpass filters connected to two
dual-switch units, one of said two dual-switch units coupled to a W-CDMA down converter and demodulation and another of said two dual-switch units coupled to an UWB multiband down converter and demodulation, and both of said W-CDMA down converter and
demodulation and said UWB multiband down converter and demodulation coupled to an analog-to-digital (A/D) converter unit; said A/D converter unit having two switch units that are controllable, each of the two switch units having two inputs and one
output, and 8 A/D converters; and said MIMO-based dual-mode W-CDMA and UWB filtering and multicarrier unit coupled to the N antennas.
2. The multiband MIMO-based dual-mode portable communication system of claim 1 wherein each of said two dual-switch units having two internal switches is controlled by said W-CDMA and UWB OFDM multiband control processor unit to provide
information from the two analog bandpass filters either to the W-CDMA down converter and demodulation or to the UWB multiband down converter and demodulation.
3. The multiband MIMO-based dual-mode portable communication system of claim 2 wherein said one of the two dual-switch units coupled to the W-CDMA down converter and demodulation is used during a W-CDMA operation or said another of the two
dual-switch units coupled to the UWB multiband down converter and demodulation is used during an UWB operation.
4. The multiband MIMO-based dual-mode portable communication system of claim 1 wherein said UWB multiband has four UWB frequency bands within a frequency range from greater than 3.1 GHz to less than 5.15 GHz, each of the four UWB frequency
bands having approximate 512 MHz with a magnitude below -41.3 dBm.
5. The multiband MIMO-based dual-mode portable communication system of claim 4 wherein said P W-CDMA and UWB portable stations uses any one of said four UWB frequency bands or any combination of said four UWB frequency bands during the UWB
operation.
6. The multiband MIMO-based dual-mode portable communication system of claim 1 wherein said eight A/D converters has the same sampling rate and bit resolution, two of the eight A/D converters coupled to the two switch units that are
controllable.
7. The multiband MIMO-based dual-mode portable communication system of claim 6 wherein said two switch units connect either two W-CDMA input signals or two UWB input signals.
8. The multiband MIMO-based dual-mode portable communication system of claim 6 wherein said only two of the eight A/D converters operate in parallel during a W-CDMA receiver mode.
9. The multiband MIMO-based dual-mode portable communication system of claim 7 wherein said eight A/D converters operate in parallel and said two switch units that are coupled to two of the eight A/D converters connect to the two UWB input
signals during an UWB receiver mode.
10. The multiband MIMO-based dual-mode portable communication system of claim 1 wherein said multiband rake receiver and decoder unit further includes twelve complex modulations, twelve digital filters, twelve despreaders and rake units, a MUX,
a long code user-p mask, a long code generator, a XOR, a deinterleaver, a desymbol repetition, and a decoder.
11. The multiband MIMO-based dual-mode portable communication system of claim 1 wherein said UWB OFDM multiband baseband processor unit further includes a combination section of a digital receiver filter unit, a multiband dispreading unit, and
a time-domain equalizer (TEQ) unit, four serial-to-parallel (S/P), four guard removing, four combinations of fast Fourier transform (FFT) and frequency-domain equalizer (FEQ), five parallel-to-serial (P/S), and a despreading, deinterleaver and decoding
unit.
12. The multiband MIMO-based dual-mode portable communication system of claim 11 wherein said combination section of the digital receiver filter unit, the multiband dispreading unit, and the TEQ unit further contains eight digital receiver
filters, eight-XOR, four-multiband-despreading, four-MUX, and four-TEQ.
13. The multiband MIMO-based dual-mode portable communication system of claim 11 wherein each of the four combinations of the FFT and the FEQ further includes a FFT having 1024 inputs, 512 outputs and 512 disable outputs, 500 of the 512 outputs
are connected to 500 N-tap equalizers followed by 500 decision detector units, and an adaptive algorithm, which is used to update the 500 N-tap equalizers.
14. A dual-mode Wideband Code Division Multiple Access (W-CDMA) and Ultra-Wideband (UWB) communication receiver comprising: two antennas coupled to a Multiple-Input-Multiple-Output (MIMO)-based dual-mode W-CDMA and UWB filtering and
multicarrier radio frequency (RF) section; the MIMO-based dual-mode W-CDMA and UWB filtering and multicarrier RF section are connected to a W-CDMA baseband processor, an UWB OFDM multiband baseband processor, and a W-CDMA and UWB Orthogonal Frequency
Division Multiplexing (OFDM) multiband control processor; the W-CDMA and UWB OFDM multiband control processor coupled to the W-CDMA baseband processor, the UWB OFDM multiband baseband processor, and a sharing memory bank; the sharing memory bank also
coupled to the W-CDMA baseband processor, and the UWB OFDM multiband baseband processor; the UWB OFDM multiband baseband processor using an UWB multiband; the UWB multiband having four frequency bands within the frequency range from greater than 3.1
GHz to less than 5.15 GHz and a magnitude below -41.3 dBm; the MIMO-based dual-mode W-CDMA and UWB filtering and multicarrier RF section further including two low noise amplifiers, two automatic gain controllers, two analog bandpass filters, two
dual-switch units, a W-CDMA down converter and demodulation, an UWB multiband down converter and demodulation, and an analog-to-digital (A/D) converter unit; and the A/D converter unit having the same type of eight A/D converters that can operate at a
sampling rate of 540 MHz.
15. The dual-mode W-CDMA and UWB communication receiver of claim 14 wherein said UWB OFDM multiband baseband processor deals with four UWB-OFDM frequency bands, with each frequency band having 512 MHz approximately.
16. The dual-mode W-CDMA and UWB communication receiver of claim 14 wherein only two among the eight A/D converters are operated producing an oversampling rate of 36 times for W-CDMA input signals.
17. The dual-mode W-CDMA and UWB communication receiver of claim 14 wherein eight A/D converters are operated in parallel for UWB input signals, each A/D converter having a 540-MHz sampling rate. |
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Description |
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BACKGROUND
This invention is generally relative to a multiband Multiple-Input-Multiple-Output (MIMO)-based Wideband Code Division Multiple Access (W-CDMA) and Ultra Wideband (UWB) Communications for wireless and/or local-area wireless communications.
A MIMO is a multiple-input-multiple-output as a wireless link and is also a space-time signal processing. In the space-time signal processing a natural dimensional of transmitting data is complemented with a spatial dimension inherent in the use
of multiple spatially distributed antennas. Thus this leads that the MIMO is able to turn multipath propagation into benefit for a user. In a MIMO system, signals on the transmit antennas and the receiver antennas are integrated in such a way that a
quality of bit error rate (BER) or a data rate of the communication for each user or a transmitting distance is improved, thereby increasing a communication network's quality of service.
The next-generation wireless communication is defined to allow a subscriber to access World Wide Web or to perform file transferring over packet data connections capable of providing 144 kbps and 384 kbps for a mobility, and 2 Mbps in an indoor
environment. The W-CDMA is a wideband, spread spectrum radio interface that uses CDMA technology to meet the needs for the next-generation wireless communication. The W-CDMA (also known as CDMA2000) supports for a wide range of radio frequency (RF)
channel bandwidths from 1.25 MHz to 15 MHz operating at 1.90 GHz band, where the channel sizes of 1, 3, 6, 9, and 12.times.1.25 MHz. A wide channel of the W-CDMA offers any combination of higher data rates, thereby enhancing total capacity. The W-CDMA
also employs a single carrier and a multicarrier system, which can be deployed as an overlay over one or more existing the second generation of TIA/EIA-95B1.25 MHz channels. In a multicarrier system, modulation symbols are de-multiplexed onto N separate
1.25 MHz carriers. Each carrier is spread with a 1.2288 Mcps chip rate.
With regard to the UWB communications, U.S. Federal Communications Commission (FCC) released a revision of Part 15 of Commission's rules for UWB transmission systems on Apr. 22, 2002. FCC permitted the marketing and operation of certain types
of new products, incorporating UWB technology. Thus, UWB communication devices can operate using spectrum occupied by existing radio service without causing interference. This results permitting scarce spectrum resources to be used more efficiently.
The UWB communication devices can offer significant benefits for Government, public safety, businesses and consumers under an unlicensed basis of an operation spectrum.
FCC is adapting unwanted emission limits for the UWB communication devices that are significantly more stringent than those imposed on other Part 15 devices. For an indoor UWB operation, FCC provides a wide variety of the UWB communication
devices, such as high-speed home and business networking devices under the Part 15 of the Commission's rules subject to certain frequency and power limitations. However, the UWB communication devices must operate in the frequency band ranges from 3.1
GHz to 10.6 GHz, and have an emission of -10 dBm for the indoor UWB operation. In addition, the UWB communication devices should also satisfy the Part 15.209 limit for the frequency band below 960 MHz. Table 1 lists the FCC restriction of the emission
masks (dBm) along with the frequencies (GHz) for the UWB communication devices in an indoor environment.
TABLE-US-00001 TABLE 1 Frequency (MHz) EIRP (dBm) 0-960 -41.3 960-1610 -75.3 1610-1990 -53.3 1990-3100 -51.3 3100-10600 -41.3 Above 10600 -51.3
The UWB communication devices are defined as any devices where a fractional bandwidth (FB) is greater than 0.25 based on the following formula:
.times. ##EQU00001## where f.sub.h is the upper frequency of -10 dBm emission point, and f.sub.L is the lower frequency of -10 dBm emission point. A center transmission frequency F.sub.c of the UWB communication devices is defined as an average
of the upper and lower -10 dBm emission points as follows:
##EQU00002## Furthermore, a minimum frequency bandwidth of 500 MHz must be used for indoor UWB communication devices regardless of the center frequency.
The UWB communication devices can be designed to use for wireless broadband communications within a short-distance range, particularly for a very high-speed data transmission suitable for broadband access to networks in the indoor environment.
A multiband MIMO-based W-CDMA and UWB communication transceiver system is disclosed herein according to some embodiments of the present invention. The invention system includes a W-CDMA base station, a UWB base station, and P-user dual-mode
portable stations of W-CDMA and UWB communication devices. The W-CDMA base station has a multicarrier for 12 channels with a total of 15 MHz frequency bandwidth at the center of 1.9 GHz frequency band, and employs four antennas at the transmitter and
receiver. The UWB communication base station uses a multicarrier for four frequency bands (referred to as a multiband) with a total of 2.048-GHz frequency bandwidth in the frequency range from 3.1 GHz to 5.15 GHz, and also employs four antennas at the
transmitter and receiver. Each of the frequency bands in the UWB communications has a 512-MHz frequency bandwidth, using an Orthogonal Frequency Division Multiplexing (OFDM) modulation. On the other hand, each of the P-user dual-mode portable stations
of the W-CDMA and UWB communication devices uses two antennas, and shares some of common components, such as analog-to-digital (A/D) and digital-to-analog (D/A) converters, memory, etc. The W-CDMA in the dual-mode portable stations uses 12 channels with
each channel of 1.25 MHz, has a multicarrier, and is able to transmit a data rate more than 2 Mcps, while the UWB employs four frequency band-based multicarrier OFDM with each frequency band of 512 MHz, and can transmit a data rate up to 1.5872 Gbps. In
addition, all of the dual-mode portable station use a direct sequence spread spectrum (DSSS), which is a pseudorandom (PN) sequence to spread a user signal. The DSSS is used to separate signals coming from multiuser. Thus, multiple access interference
(MAI) among multiuser can be avoided when a set of PN sequences is designed with as low cross-correlation as possible.
An OFDM is an orthogonal multicarrier modulation technique that has its capability of multifold increasing symbol duration. Increasing the number of subcarriers in the OFDM modulation, the frequency selectivity of a channel may be reduced so
that each subcarrier experiences flat fading for the UWB communications. Thus, an OFDM approach is a particular useful for the UWB communications over a short-range fading channel.
The present invention of the multiband MIMO-based W-CDMA and UWB communications utilizes both benefits of W-CDMA wireless phones and UWB wireless broadband communications. Such a dual-mode device not only can transmit the packet data in a form
of wireless phone but also can use as a very-high speed wireless broadband Internet device to transmit and receive data, image, video, video game, music, and stock graph, etc., in a real-time. Thus, there is a continuing need of the multiband MIMO-based
W-CDMA and UWB communication transceiver system for delivering a very-high data rate with a capability of flexibility and scalability in a combination form of the wireless and fixed wireless environment.
SUMMARY
In accordance with one aspect, a multiband MIMO-based dual-mode portable station of W-CDMA and UWB communication receiver comprises a MIMO-based dual-mode W-CDMA and UWB filtering and multicarrier Radio Frequency (RF) section, a W-CDMA baseband
processor, an UWB OFDM multiband baseband processor, a W-CDMA and UWB OFDM multiband control processor, and a multiple antenna unit.
Other aspects are set forth in the accompanying detailed description and claims.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a block diagram of shewing a multiband MIMO-based W-CDMA and UWB communication transceiver system including P-user dual-mode portable stations of W-CDMA and UWB, and two different base stations of the W-CDMA and UWB communication
according to some embodiments.
FIG. 2 is a block diagram of a MIMO-based W-CDMA base station employing four antennas according to some embodiments.
FIG. 3 is a detailed block diagram of a W-CDMA baseband processor of the base station according to some embodiments.
FIG. 4 is a detailed block of a MIMO-based W-CDMA filtering and multicarrier RF section according to some embodiments.
FIG. 5 is a detailed block diagram of a W-CDMA mapping, spreading, and filtering section according to some embodiments.
FIG. 6 is a detailed block diagram of a W-CDMA analog filtering and multicarrier modulation section according to some embodiments.
FIG. 7 is a block diagram of a MIMO-based UWB base station according to some embodiments.
FIG. 8 is a detailed block diagram of an UWB base station according to some embodiments.
FIG. 9 is a detailed block diagram of a MIMO-based UWB spreading and filtering section according to some embodiments.
FIG. 10 is a detailed block diagram of a MIMO-based UWB modulation and multicarrier RF section according to some embodiments.
FIG. 11 is a frequency spectrum output of the MIMO-based UWB base station transmitter for the indoor operation according to one embodiment.
FIG. 12 is a block diagram of a W-CDMA and UWB portable station for a single user according to some embodiments.
FIG. 13 is a detailed block diagram of a MIMO-based dual-mode 3G W-CDMA and UWB filtering and multicarrier RF section according to some embodiments.
FIG. 14 is a detailed block diagram of a W-CDMA down converter and demodulation according to some embodiments.
FIG. 15 is a detailed block diagram of an UWB multiband down converter and demodulation according to some embodiments.
FIG. 16 is a detailed block diagram of an analog-to-digital converter according to some embodiments.
FIG. 17 is a detailed block diagram of a W-CDMA baseband processor in the dual-mode portable station according to some embodiments.
FIG. 18 is a detailed block diagram of a W-CDMA multiband rake receiver and decoder unit according to some embodiments.
FIG. 19 is a detailed block diagram of a UWB OFDM multiband baseband processor according to some embodiments.
FIG. 20 is a detailed block diagram of a combination section of a digital receiver filter unit, a multiband despreading unit, and a time-domain equalizer (TEQ) unit according to some embodiments.
FIG. 21 is a detailed block diagram of a combination section of a fast Fourier transform (FFT) unit and a frequency-domain equalizer (FEQ) unit according to some embodiments.
FIG. 22 is a detailed block diagram of a despreading, deinterleaver, and decoding unit according to some embodiments.
DETAILED DESCRIPTION
Some embodiments described herein are directed to the multiband MIMO-based W-CDMA and UWB transceiver system for wireless and fixed wireless communications. Such a dual-mode transceiver system can be implemented in hardware, such as in an
Application Specific Integrated Circuits (ASIC), digital signal processor, field programmable gate array (FPGA), software, or a combination of hardware and software.
Multiuser MIMO-Based 3G W-CDMA and UWB System
A multiuser MIMO-based W-CDMA and UWB system 100 for the wireless and fixed wireless communications is shown in FIG. 1 in accordance with one embodiment of the present invention. Dual-mode W-CDMA and UWB portable stations from 110a to 110p can
simultaneously communicate with either a MIMO-based W-CDMA base station 140 or a MIMO-based UWB base station 170 to transmit and receive information data. The dual-mode W-CDMA and UWB portable station 110a transmits and receives the W-CDMA or the UWB
information data through its two antennas of 120a.sub.1 and 120a.sub.2. The base station of the W-CDMA 140 or the UWB base station 170 communicates with the dual-mode W-CDMA and UWB portable station 110a through the W-CDMA's four antennas from 130a to
130d or through the UWB's four antennas from 160a to 160d, respectively. In a similar way, other dual-mode W-CDMA and UWB portable stations from 110b to 110p also transmit and receive the information data through their antennas from 120b.sub.1 and
120b.sub.2 to 120p.sub.1 and 120p.sub.2, respectively, and communicate with either the W-CDMA base station 140 through the antennas from 130a to 130d or the UWB base station 170 through the antennas from 160a to 160d. The W-CDMA base station 140 is
coupled to a W-CDMA network interface section 150, which is connected with a W-CDMA network 152. The UWB base station 170 is connected with an UWB network interface section 180 that is coupled to an UWB network 182.
The MIMO-based W-CDMA base station 140 can transmit multiuser's information data at the same time. After scrambling with a long code corresponding to user p, the user data is de-multiplexed onto N carriers, where N equals to 3, 6, 9, or 12. On
each carrier, the demultiplexed bits are mapped onto I and Q followed by using Walsh spreading. For reverse closed loop power control, power control bits may be punctured onto the forward link channel at a rate of 800 Hz. Then, a signal on each carrier
is orthogonally spread by an appropriate Walsh code function in such a way that a fixed chip rate of 1.2288 Mcps can be maintained per carrier. Walsh codes may differ on each carrier. The signal on each carrier is then complex PN spread followed by
using a baseband filtering and binary phase-shifted keying (BPSK) or quaternary phase-shifted keying (QPSK) modulation. The W-CDMA base station 140 can transmit and receive the data rate from 144 kbps to greater than 2 Mbps and supports a wide range of
RF channel bandwidths, including 1.25 MHz, 3.75 MHz, 7.5 MHz, 11.25 MHz, and 15 MHz.
The MIMO-based UWB base station 170, knowing all of the UWB PN sequences of the dual-mode W-CDMA and UWB portable stations from 110a to 110p, can transmit and receive all of the UWB information data from all of the dual-mode W-CDMA and UWB
portable stations from 110a to 110p by spreading and despreading of the user PN sequences on the multiband. The MIMO-based UWB base station 170 uses a BPSK or a QPSK modulation and a carrier for each of the multiband to transmit and receive the
information data rate of 396.8 Mbps on one frequency band. As a result, the MIMO-based UWB base station 170 can simultaneously transmit and/or receive the maximum data rate up to 1.5872 Gbps by using all of the four frequency bands. In addition, the
UWB base station 170 is able to transmit the data rate with an enhancement of a longer range due to use the multiple antennas.
3G W-CDMA Base Station Transmitter Architecture
FIG. 2 is a block diagram 200 of the MIMO-based W-CDMA base station 140 according to some embodiments. The MIMO-based W-CDMA base station 140 includes a W-CDMA baseband processor 210, a MIMO-based W-CDMA filtering and multicarrier RF section 220
coupled to four antennas from 130a to 130d, and a W-CDMA control processor 230. The W-CDMA baseband processor 210 deals with a multiuser digital signal processing of a physical layer including turbo or convolution encoder and decoder, block interleaver
and deinterleaver, spreading and dispreading. The MIMO-based W-CDMA filtering and multicarrier RF section 220 provides filtering, modulation, and transmits W-CDMA signal through the antennas from 130a to 130d. The W-CDMA control processor 230 supports
a data frame information, and controls the W-CDMA baseband processor 210 and the MIMO-based W-CDMA filtering and multicarrier RF section 220.
The MIMO-based W-CDMA base station 140 is able to transmit and receive multiuser information data through multichannel with multicarrier simultaneously. There are a total of 12 multicarriers for a wide range of RF channel bandwidths of 1.25 MHz,
3.75 MHz, 7.5 MHz, 11.25 MHz, and 15 MHz. The signal on each carrier is orthogonally spread by the appropriate Walsh code at the chip rate of 1.2288 Mcps. Then, the signal on each carrier is filtered and modulated by using the baseband filtering and
BPSK or QPSK modulation. The MIMO-based W-CDMA base station 140 can transmit and/or receive the data rate from 144 kbps to more than 2 Mbps.
Referring to FIG. 3 is a detailed block diagram 300 of the W-CDMA baseband processor 210 according to some embodiments. A turbo or convolution encoder 310 that is used to encode the user information data is coupled to a symbol repetition 320.
The symbol repetition 320 can repeat a frame symbol data with 2-time, 4-time or 8-time. The output of the symbol repetition 320 is interleaved by using a block interleaver 330. The output data of the block interleaver 330 is scrambled with a long code
from a bit selector 360 by using an exclusive OR (XOR) 370. A long code mask for user p 340 is coupled to a long code generator 350 that is connected with a bit selector 360. The scrambled data of the XOR 370 output is demultiplexed onto 12 parallel
data labeled from d.sub.1 to d.sub.12 by using a demultiplexer 380.
FIG. 4 is a block diagram 400 of the MIMO-based W-CDMA filtering and multicarrier RF section 220 according to some embodiments. The MIMO-based 3G W-CDMA filtering and multicarrier RF section 220 includes a W-CDMA mapping spreading and filtering
410 and a W-CDMA analog filtering and multicarrier modulation 420. The W-CDMA mapping spreading and filtering 410 is coupled to the W-CDMA analog filtering and multicarrier modulation 420. The 12 parallel signals from d.sub.1 to d.sub.12 are passed
through the W-CDMA mapping spreading and filtering 410 to produce 12 parallel output signals, which are used as the input signals for the W-CDMA analog filtering and multicarrier modulation 420. Then the W-CDMA analog filtering and multicarrier
modulation 420 produces four parallel signals for the transmitter through four antennas from 130a to 130d.
Referring to FIG. 5 is a detailed block diagram 500 of the W-CDMA mapping, spreading and filtering 410 according to some embodiments. The 12 parallel input signals from d.sub.1 to d.sub.12 are passed through 12 MUX and IQ mapping units from 510a
to 510m. The output I and Q signals of the MUX and IQ mapping units from 510a to 510m are spread by using Walsh codes from W.sub.m1 to W.sub.m12, respectively. Then signals are complex PN spread by using complex PN spreading units from 530a to 530m,
followed by baseband filters from 540a.sub.1 and 540a.sub.2 to 540m.sub.1 and 540m.sub.2. Analog-to-digital (A/D) converter units from 550a.sub.1 and 550a.sub.2 to 550m.sub.1 to 550m.sub.2 convert all of the digital signals of the baseband filter
outputs from 540a.sub.1 and 540a.sub.2 to 540m.sub.1 and 540m.sub.2 into parallel analog signals from a.sub.11 and a.sub.12 to a.sub.121 and a.sub.122.
Referring to FIG. 6 is a detailed block diagram 600 of the W-CDMA analog filtering and multicarrier modulation 420 according to some embodiments. The input signals from a.sub.11 and a.sub.12 to a.sub.121 and a.sub.122 are in parallel passed
through analog filters from 610a.sub.1 and 610a.sub.2 to 610m.sub.1 and 610m.sub.2 to produce reconstructed analog signals. Each pair of the output signals of the analog filters from 610a.sub.1 and 610a.sub.2 to 610m.sub.1 and 610m.sub.2 is performed
QPSK modulation with multicarrier by using each pair of multipliers 620a.sub.1 and 620a.sub.2 and one addition 630a.sub.1 to multipliers 620m.sub.1 and 620m.sub.2 and one addition 630m, respectively. The 12 QPSK signals with multicarriers are grouped
together into four signals by using four additions from 640a to 640d, respectively, followed by four baseband filters (BPF) from 650a to 650d to produce signals for power amplifier and antennas.
FIG. 7 is a block diagram 700 of the MIMO-based UWB base station 170 according to some embodiments. An UWB baseband processor 710, which performs convolution encoder and decoder, interleaver and deinterleaver, and inverse fast Fourier transform
(IFFT) and fast Fourier transform (FFT) functions, is coupled to a MIMO-based UWB spreading and filtering 720, followed by a MIMO-based UWB modulation and multicarrier RF section 730. The MIMO-based UWB modulation and multicarrier RF section 730 is
connected with four antennas from 160a to 160d. An UWB control processor 740 is used to control a frame information and entire process among the units of the MIMO-based UWB base station 170, the MIMO-based UWB spreading and filtering 720, and MIMO-based
UWB modulation and multicarrier RF section 730.
Referring to FIG. 8 is a detailed block diagram 800 of the UWB baseband processor 710 according to some embodiments. There are a number of p users from a user-1 bitstream 810a to a users bitstream 810p, respectively. The user-1 bitstream 810a
is coupled to a 1/2-rate convolution encoder 812a that is connected to an interleaver 814a. Using a unique PN sequence of a user-1 key 822a spreads the output sequence of the interleaver 814a. In a similar way, the user-p bitstream 810p is coupled to
the 1/2-rate convolution encoder 812p that is connected to the interleaver 814p. Using the unique PN sequence of the user-p key 822p spreads the output sequences of the interleaver 814p. All of the PN sequences of the user-1 key 822a to the users key
822p are orthogonal each other. This means that a cross-correlation between one PN sequence and other PN sequences is almost zero, while a self-correlation of a user PN sequence is almost equal to one. Then, the p output sequences from the interleaver
814a to the interleaver 814p in a parallel operation are added together to form a serial sequence output by using a sum over block duration 830. The serial output of the sum over block duration 830 is converted into four parallel sequences by using a
polyphase-based multiband 840. Thus, the first of the output sequence from the polyphase-based multiband 840 is converted into a 512-parallel sequence by using a serial-to-parallel (S/P) 850a. The 512-parallel sequence is formed to a 512-parallel
complex sequence with symmetric conjugates. The 512-parallel complex sequence is passed through an IFFT 852a to produce a 1024-parallel real sequence. The IFFT 852a is coupled to a guard 854a to insert 256 samples as a guard interval for the output
sequence of the IFFT 852a. As a result, the output of the guard 854a is a 1280-parallel real sequence. Then, the outputs of the guard 854a are used to form a serial signal p.sub.1 by using a parallel-to-serial (P/S) 856a. In the same way, the fourth
of the output sequence from the polyphase-based multiband 840 is converted into a 512-parallel sequence by using a S/P 850k. The 512-parallel sequence is formed to a 512-parallel complex sequence with symmetric conjugates. The 512-parallel complex
sequence is passed through an IFFT 852d to produce a 1024-parallel real sequence. The IFFT 852d is coupled to a guard 854d to insert 256 samples as a guard interval for the output sequence of the IFFT 852d. Thus, the output of the guard 854d is a
1280-parallel real sequence. The guard interval is used to avoid an intersymbol interference (ISI) between IFFT frames. Finally, the outputs of the guard 854d are used to form a serial signalp.sub.4 by using a P/S 856d.
The data rate-dependent parameters of the 1024-point IFFT operation 852 is listed in Table 2 for each of the frequency bands as follows:
TABLE-US-00002 TABLE 2 Four band One frequency frequency Coded bits Coded bits Data bits per data rate band data rate Coding per sub- per OFDM OFDM (Gbits/s) (Mbits/s) Modulation rate carrier symbol symbol 0.7936 198.4 BPSK 1/2 1 992 496 1.5872
396.8 QPSK 1/2 2 1984 992
The corresponding 1024-point IFFT of detailed timing-related parameters for each of the frequency bands is listed in Table 3:
TABLE-US-00003 TABLE 3 Parameters Descriptions Value N.sub.ds Number of data subcarriers 992 N.sub.ps Number of pilot subcarriers 8 N.sub.ts Number of total subcarriers 1000 D.sub.fs Frequency spacing for subcarrier (512 0.5 MHz MHz/1024)
T.sub.FFT IFFT/FFT period (1/D.sub.fs) 2.0 .mu.s T.sub.gd Guard duration (T.sub.FFT/4) 0.5 .mu.s T.sub.signal Duration of the signal BPSK-OFDM symbol 2.5 .mu.s (T.sub.FFT + T.sub.gd) T.sub.sym Symbol interval (T.sub.FFT + T.sub.gd) 2.5 .mu.s T.sub.short
Short duration of training sequence (10 .times. 5.0 .mu.s T.sub.FFT/4) T.sub.gd2 Training symbol guard duration 1.0 .mu.s (T.sub.FFT/2) T.sub.long Long duration of training sequence (2 .times. T.sub.FFT + 5.0 .mu.s T.sub.gd2) T.sub.preamble Physical
layer convergence procedure preamble 10.0 .mu.s duration (T.sub.short + T.sub.long)
Referring to FIG. 9 is a detailed block diagram 900 of the MIMO-based spreading and filtering section 720 according to some embodiments. There are four input signals from p.sub.1 to P.sub.4. The input signal of p.sub.1 is demultiplexed by using
a demultiplexer 910a to produce I and Q signals. The I and Q signals are spread with an output sequence of a multiband spreading 930a by using XORs of 920a and 920b to produce spread I and Q signals, followed by two transmitter shaped filters of 940a,
and 940a.sub.2, respectively. Then, the output signals of the transmitter shaped filters of 940a.sub.1 and 940a.sub.2 are passed through two D/A converters of 950a.sub.1 and 950a.sub.2, followed by two analog filters of 960a.sub.1 and 960a.sub.2 to
smooth the analog signals, respectively. In the same way, the input signal of p.sub.4 is demultiplexed by using a demultiplexer 910d to produce I and Q signals. The I and Q signals are spread with an output sequence of a multiband spreading 930d by
using XORs 920d.sub.1 and 920d.sub.2 to produce spread I and Q signals, followed by two transmitter shaped filters of 940d.sub.1 and 940d.sub.2, respectively. Then, the output signals of the transmitter shaped filters of 940d.sub.1 and 940d.sub.2 are
passed through two D/A converters of 950d.sub.1 and 950d.sub.2, followed by two analog filters of 960d.sub.1 and 960d.sub.2 to smooth the analog signals, respectively. Thus, the MIMO-based spreading and filtering section of 720 converts four digital
sequences onto four I and four Q spread analog signals with multicarrier for transmitter section.
Referring to FIG. 10 is a detailed block diagram 1000 of the MIMO-based UWB modulation and multicarrier RF section 730 according to some embodiments. The input signals from I.sub.1 and Q.sub.1 to I.sub.4 and Q.sub.4 are modulated in a QPSK
format with multicarriers by using multipliers of 1010a.sub.1 and 1010a.sub.2 and an addition from 1012a to 1010d.sub.1 and 1101d.sub.2 and an addition 1012d to produce RF signals from o.sub.1 to o.sub.2. Then, the signals from o.sub.1 to o.sub.2 are
summed together to form four RF signals with multicarriers by using additions from 1020a to 1020d, followed by using analog bandpass filters from 1030a to 1030d. The output RF signals of the analog bandpass filters from 1030a to 1030d are passed through
the power amplifier (PA) from 1040a to 1040d onto antennas.
Spectrums of MIMO-Based UWB Base Station Transmitter
FIG. 11 is an output frequency spectrum 1100 of the MIMO-based UWB base station communication transmitter, including four frequency band spectrums of 1120, 1130, 1140 and 1150 according to some embodiments. A FCC emission limitation 1110 for the
indoor UWB operation is also shown in FIG. 11. Each transmitter frequency bandwidth of all the frequency band spectrums of 1120, 1130, 1140 and 1150 is 512 MHz and is fitted under the indoor FCC emission limitation 1110 with different carrier
frequencies. The detail positions of each frequency band spectrums (dBm) along with the center, lower and upper frequencies (GHz) as well as the channel frequency bandwidth (MHz) are listed in Table 4:
TABLE-US-00004 TABLE 4 Center Lower Frequency Multichannel Frequency Frequency Upper Frequency Bandwidth Label (GHz) (GHz) (GHz) (MHz) 1120 3.357 3.101 3.613 512 1130 3.869 3.613 4.125 512 1140 4.381 4.125 4.637 512 1150 4.893 4.637 5.149 512
During the indoor UWB operation, the MIMO-based UWB base station transmitters can avoid interference with wireless local area network (WLAN) 802.11a lower U-NII frequency band in the frequency range of 5.15 GHz to 5.35 GHz since the highest
spectrum of the MIMO-based UWB base station transmitter is at 5.149 GHz, which is lower than 5.15 GHz in WLAN 802.11a lower band.
Dual-Mode MIMO-based Receiver of 3G W-CDMA and UWB Portable Station
FIG. 12 is a block diagram 1200 of a dual-mode MIMO-based receiver of the W-CDMA and UWB portable station 110a according to some embodiments. A dual-mode MIMO-based W-CDMA, UWB filtering and multicarrier RF section 1210 receives RF signals from
two antennas of 120a.sub.1 and 120a.sub.2 and converts RF signals to either W-CDMA digital signals or UWB digital signals. The dual-mode MIMO-based W-CDMA, UWB filtering and multicarrier RF section 1210 is coupled to a W-CDMA baseband processor 1220 and
an UWB OFDM multiband baseband processor 1230. During the W-CDMA mode, the W-CDMA baseband processor 1220 receives the W-CDMA digital signals from the dual-mode MIMO-based W-CDMA, UWB filtering and multicarrier RF section 1210 to perform digital
filtering, demultiplexer, rake receiver, dispreading, deinterleaver, and decoding processes. During the UWB | | |
