KR100818173B1 - High speed digital sampler and Short range noncoherent impulse radio communication system using high speed digital sampler - Google Patents

Abstract

The present invention relates to a transmitter (Tx) signal processor, an integrated impulse generator capable of implementing a simple ON-OFF-Keying modulation scheme, and a transmitter RF including an amplifier for amplifying an impulse generator output; A receiver RF including a two stage envelope detector for detecting a received signal and a comparator for converting the detected signal into a rectangular pulse; A signal restoring unit using a high speed digital sampler to recover a signal transmitted from a receiving RF; A signal processor including a reception (Rx) signal processor for decoding the detected signal; And an ultra-wideband antenna for transmitting / receiving an ultra-wideband signal. A short-time impulse non-coherent wireless communication system using a high-speed digital sampler and a time delay or phase shift element are added to add a time delay or phase shift element. A clock generator for generating at least one clock having a system and the system clock and at least one clock in parallel structure and a pulse detector for applying a system clock and at least one clock to the received signal to detect a modulated received signal It relates to a high-speed digital sampler comprising a.

Ultra-Wideband, Impulse, Digital Sampler, Time interleaving, Impulse Signal Synchronization, On-Off-King (OOK), Integrated Impulse Generator, High Speed Wideband A / D Converter

Description

High speed digital sampler and short range noncoherent impulse radio communication system using high speed digital sampler

1 is a diagram schematically showing an embodiment of a short range impulse asynchronous wireless communication system using a high speed digital sampler according to the present invention;

2 is a diagram illustrating an embodiment of an integrated impulse generator of a transmitter RF of a wireless communication system according to the present invention;

3A is a diagram illustrating a form in which a transmission module including a transmitter RF and an ultra-wideband antenna as shown in FIG. 2 is printed on a printed board,

FIG. 3B is a view showing an actual manufactured form of a transmission module as shown in FIG. 3A.

3C is a diagram illustrating data output from a transmission (Tx) signal processing unit of a transmitter RF as shown in FIG. 2.

FIG. 3D is a diagram illustrating an impulse output through a band pass filter in the transmitter RF as shown in FIG.

4 is a diagram illustrating an embodiment of a receiving end RF of a wireless communication system according to the present invention;

5 is a diagram illustrating a comparator circuit using a two-stage envelope detection circuit and an OP AMP in a receiving RF of a wireless communication system according to the present invention as shown in FIG.

FIG. 6 is a diagram illustrating a spherical pulse conversion process of an impulse signal in a receiving RF of a wireless communication system according to the present invention as shown in FIG. 4.

FIG. 7 is a diagram illustrating a spherical impulse waveform graph measured through a pulse conversion process as shown in FIG. 6.

8A is a view illustrating a signal detection process for a comparator output in a high speed digital sampler according to the present invention;

FIG. 8B is a diagram illustrating a configuration and an output waveform of the clock generator as shown in FIG. 8A;

FIG. 9A is a diagram illustrating a signal detection clock timing diagram for a comparator output in a high speed digital sampler as shown in FIG. 8A;

9B is a diagram illustrating a recovery process of a signal measured using a logic analyzer in an actual impulse communication system,

10 is a view showing the configuration of a transmission (Tx) signal processing unit of a wireless communication system according to the present invention,

11 is a view showing the configuration of a reception (Rx) signal processing unit of a wireless communication system according to the present invention,

12 is a view showing a control flowchart of a transmission (Tx) signal processor and a reception (Rx) signal processor of the wireless communication system according to the present invention;

13 is a diagram illustrating a protocol for transmitting data in a wireless communication system according to the present invention.

14 is a view showing a cross section of the ultra-wideband antenna used in the wireless communication system according to the present invention,

FIG. 15 is a diagram illustrating broadband antenna reflection characteristics that may be measured when using an ultra-wideband antenna as shown in FIG. 14.

<Description of the symbols for the main parts of the drawings>

230: two-stage envelope detector

240: comparator

310: Clock generator section for high speed digital sampler

320: pulse detector

410: Rx signal processing unit

510: Transmission (Tx0 signal processing unit

520 pulse mapper

530: pulse shaper

The present invention relates to a wireless communication system, and more particularly, a simplified ON-OFF-Keying method and a noncoherent receiver using an ultra-wideband impulse that can be used in an intelligent home network and a ubiquitous sensor network, and a high speed sampler. The present invention relates to an ultra-wideband impulse communication system capable of high-speed communication of several Mbps or less at low power within a few tens of meters using low power.

The UWB can be classified into two categories by the Federal Communications Commission, which is defined as a system with a fractional bandwidth of 0.2 or more, or a -10 dB bandwidth of 500 MHz or more.

f _u : upper frequency below 10 dB below maximum,

f _l : sub-frequency below 10 dB below maximum,

f _u -f _l : -10dB bandwidth, (f _u + f _l ) / 2: center frequency

According to the definition of UWB, UWB communication has been promoted in three directions. This is the DS-UWB method using direct sequences for high speed data transmission, the MB-OFDM method using a combination of several bands having a 500 MHz bandwidth, and the ultra wide band impulse which uses an ultra-short impulse in the time domain. Technology IR-UWB. Among them, the ultra-wideband impulse technology The IR-UWB method has been known as a 'carrier-free', 'baseband', or 'impulse' technology since the early 1960s, and it has a secretion characteristic in communication. This good, used signal has a wide band characteristics and high resolution characteristics has been used a lot for military purposes. The concept is a very short period of radio frequency energy, typically between tens of picoseconds (one trillionth of a second) and several nanoseconds (one billionth of a second), and an instantaneous (burst) signal during Send and receive wirelessly. These burst signals are called "carrier-free" because they have an extremely wide band in the frequency domain and are difficult to determine the RF center frequency in practice. Signal generation is in the form of 'non-RF' signals, which generate 'impulses' and use broadband microwave antennas to radiate the signal into space.

In such ultra-wideband (UWB) communication, unlike a wireless communication system using conventional continuous sinusoidal waves, since a very short width is used in the time domain and a pulse having the ultra-wide frequency spectrum in the frequency domain, There is an advantage in that high-speed data can be transmitted using transmission energy of. In addition, the use of an ultra-short impulse, it can be applied to the production of a system with accurate time precision characteristics, it can be utilized in low power / low speed / ultra precision position tracking and recognition system. Furthermore, the radar system configuration using the signal characteristics of the ultra-wide spectrum can be used for the development of a precision radar capable of extracting a lot of information, and because of its excellent penetration characteristics that can penetrate walls and underground, the location of victims due to earthquakes or terror attacks It can be used to identify or identify underground structures.

The ultra-wideband impulse communication technology, first proposed by Time Domain in 1995, used one or more subcarriers to communicate information from an impulse radio to an impulse radio receiver. By using subcarriers, impulse radio transmissions are provided with added channelization, smoothness and fidelity, which emit Gaussian monocycle pulse trains with tightly controlled average pulse-pulse intervals. Impulse radio transmitters use pulse widths between 20 and 0.1 nanoseconds and pulse-pulse intervals between 2 and 5000 ns. These narrow mono cycle pulses have inherent wideband frequency characteristics, and the subcarriers of the different frequency waveforms can be used to add channelization of the impulse radio signal. Optionally, the encoded timing signal can be added or mixed to the modulated subcarrier, and the composite signal is used to time modulate the periodic timing signal.

Further, a full-duplex ultra wideband communication system and method (Registration No.:104029120000) In another conventional ultra wideband communication system, an impulse radio transmitter for transmitting an impulse radio signal pulse, an impulse radio receiver for receiving an impulse radio signal pulse, Means for synchronizing transmission and reception of an impulse radio signal for pulse interleaved communication in association with both or both of the impulse radio transceivers. Pulse interleaving avoids self interference between transmitted and received impulse radio signal pulses. In addition, the system avoids simultaneous operation by selectively transmitting and receiving at different repetition rates, and overlap states occur at a constant rate regardless of space distribution. The transmitting end of the system generates a Gaussian mono cycle pulse and transmits the signal directly to the antenna without using a filter. In this case, the deformation of the pulse waveform by the antenna may be serious, and the impulse propagation bandwidth is determined according to the bandwidth of the antenna. Therefore, there is a need for an antenna that satisfies the frequency bandwidth determined by the radio wave method. In addition, the system modulates an impulse using pulse position modulation. The receiver of the system uses a cross correlator using a trigger signal, and then detects a signal using an A / D converter. However, in recent years, the amount of information has increased and, in communication on the move, problems such as multipath fading, multipath time delay, radio interference, and interference between signals occur in communication using existing high or microwave frequencies. When the speed is low, there is no problem in using the classic communication method, but the complexity of the system is increased, and in particular, the use of A / D complicates power consumption and the entire system.

Another conventional technology in Korea is a wireless communication transmitter (registration number: 1004700290000) by a method for generating a Gaussian pulse and an on-off keying modulation method using the ON-OFF keying method at the Korea Electrotechnology Research Institute. This is an invention for the purpose of simplifying the device and reducing the power consumption for transmission in order to solve the complexity of the system of the related arts described above, and is a carrier wave used in the conventional wireless communication transmission device, instead of a continuous wave such as a sine wave. By using the ultra-wideband characteristics of the Gaussian monocycle pulses, a Gaussian monocycle generator for generating an ultra-wideband pulse having a constant thrust, a binary random data generator for generating binary random data, and a binary random data generator Switch means for controlling ON-OFF keying of periodic pulses generated by the Gaussian monocycle generator controlled by binary random data, filter means for limiting the bandwidth of the modulated Gaussian monocycle pulse; Amplifying means for power amplifying the output of the filter , It is configured to include an antenna for radiating the amplified signal. Impulse generation occurs by a microprocessor or a square wave oscillator, and occurs on the rising edge of the input square wave.

Here, the ultra-wideband pulse train generator (Registration No .: 1005201500000) proposed by Samsung Electronics has implemented a simpler wireless communication system using the impulse generator in the form of a chip. In the above invention, a method of designing an impulse generator in the form of a chip is proposed. The impulse generator is manufactured through a latch at an appropriate time interval with respect to an input signal. This method is not a ON-OFF-Keying method, but a signal generation technique for the BPSK method in which the signal is inverted whenever the data value changes.

However, the wireless communication systems according to the prior art including the contents of various impulse communication schemes, there is a problem that the configuration of the system is not simple due to the essential characteristics for activation of the UWB technology or the broadband characteristics of the use signal itself. In addition, in the impulse communication method, the signal restoration unit is the most essential element in the basic configuration of the system. Since the broadband signal in the time domain is several nanoseconds or less, a technique for converting the broadband impulse into a digital signal can be implemented in various ways. However, considering the complexity of the system, the cost, and the power consumption, the technology is not easily implemented. Therefore, the conventional impulse communication system does not propose a new method for recovering the wideband impulse signal into a digital signal, or uses a conventional wideband A / D converter. In the case of using the conventional A / D converter, the complexity of the system is increased and power consumption is generated, thereby increasing the price of the entire system and making it difficult to implement a low complexity and low power system, which is an advantage of impulse communication.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned requirements of the prior art, and the digital impulse signal using an integrated impulse generation device of a simpler ON-OFF-Keying transmitter, a noncoherent receiver and a high-speed digital sampler. It is an object of the present invention to provide a short-range impulse asynchronous wireless communication system using a high-speed digital sampler that enables a simple device, a power consumption for transmission, and high-speed data transmission through a signal recovery device. In particular, by presenting the signal processing component for the whole system, we have developed a short range communication system with actual low and low speed, low power, and low complexity system to control home network home appliances, sensor network, low power UWB-RFID, and low and low speed short range personal communication devices. It is intended to be used in.

A short-range impulse asynchronous wireless communication system using a high speed digital sampler according to the first aspect of the present invention is a wireless communication system using an ultra-wideband (UWB) impulse, comprising a transmission (Tx) signal processor and simple ON-OFF-Keying modulation. A transmitter RF including an integrated impulse generator capable of implementing the scheme, and an amplifier for amplifying the impulse generator output; A receiver RF including a two stage envelope detector for detecting a received signal and a comparator for converting the detected signal into a rectangular pulse; A signal restoring unit using a high speed digital sampler for restoring a signal transmitted from the receiving end RF; A signal processing unit including a reception (Rx) signal processing unit for decoding the detected signal; And an ultra-wideband antenna for transmitting and receiving the ultra-wideband signal.

Here, the high speed digital sampler includes a clock generator unit having a time delay element and a pulse detector for detecting a rectangular pulse. The clock generator unit generates a clock having a higher frequency than the system clock, and generates a clock signal. Applies and detects a modulated received signal, and adds a time delay or phase conversion element to the clock generator unit to generate at least one clock having a constant time difference or phase difference from the system clock, and generates the clock signal generated by the system clock. At least one system clock may be arranged in parallel.

The receiver RF is a broadband band pass filter for preventing interference of adjacent frequencies among the signals received from the ultra-wideband antenna, a low noise amplifier for low noise amplification of the filtered signal, an active attenuator for controlling the size of the signal, signal amplification AGC (Automatic Gain Control) amplifier for the structure is connected to the two-stage envelope detector.

At this time, the transmission (Tx) signal processor is a memory capable of storing data, a forward error correction encoder, a signal generator for generating a Start & Stop signal indicating the start and end of the actual data transmission, the actual data and control The MUX for selecting data, a memory for storing data passing through the MUX, and a data mapper for receiving a data and finally forming a desired pulse train, and receiving the Rx signal. The processor may include a start / end signal generator for checking the start and end of the pulse sequence of the digital signal restored through the signal restorer, a memory for storing actual data, and a forward error correction decoder for decoding the encoded signal at the transmitter. Forward error correction decoder), and a structure consisting of a memory that finally stores the original data is preferable. Do.

Further, the ultra-wideband antenna is a rectangular monopole antenna printed stepwise on a cross section of a printed circuit board having an inclined surface, and has a feed line having a coplanar waveguide (CPW) structure, and a triangular or square transition in the feed section. ) To have broadband characteristics.

A high-speed digital sampler according to the second aspect of the present invention is a high-speed digital sampler constituting a wireless communication system using an ultra wide band (UWB) impulse, and includes a time delay or phase shift element, and a constant time difference or phase difference from the system clock. A clock generator unit for generating at least one clock having a signal and arranging the system clock and the generated at least one clock in a parallel structure, and applying the system clock and the at least one clock to a received signal and receiving the modulated signal. And a pulse detector for detecting a signal.

Hereinafter, with reference to the accompanying drawings, it will be described in detail the present invention. For convenience of description, the wireless communication system according to the present invention will be described according to the flow of signals in the order of transmitting a signal, receiving the received signal, and restoring the transmitted signal. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosure may be made thorough and complete, and to fully convey the spirit of the present invention to those skilled in the art.

1 is a diagram schematically showing an embodiment of a short range impulse asynchronous wireless communication system using a high speed digital sampler according to a first aspect of the present invention.

For example, as shown in Figure 1, the short-range impulse asynchronous wireless communication system according to the present invention is largely an ultra-wideband reception antenna 10, the receiving end RF (20), the signal recovery unit 30 using a high-speed digital sampler The signal processor 40, the transmitter RF 50, and the transmit antenna 60 may be configured. More specifically, the receiver RF 20 may include a band pass filter (BPF) 210 for passing only a signal belonging to a specific range among various received signals, and a low noise amplifier (LNA) 220 for low noise amplification of the filtered signal. And a two-stage envelope detector (230) for turning the amplified signal into a square pulse, and a comparator (240) for converting the detected signal into a square pulse. (Tx) signal processor 510, a pulse mapper 520 and a pulse shaper 530 corresponding to an integrated impulse generator capable of implementing a simple ON-OFF-Keying modulation scheme, and a communication radius An amplifier 540 for amplifying the impulse generator output to increase the power. On the other hand, the signal restorer 30 is a place where a process of restoring the RF signal passing through the receiving end RF 20 to a digital signal is made, and the process of decoding the signal detected by the signal restorer is received (Rx). The signal processor 40 includes a signal processor 410 and a Ranging & Positioning element 420.

An embodiment of the wireless communication system according to the present invention uses an asynchronous (Noncoherent) method for restoring a signal using only the size of a received impulse, and an integrated impulse generator capable of implementing a simple ON-OFF-Keying modulation scheme. Suggest a structure.

2 is a diagram illustrating an embodiment of an integrated impulse generator of a transmitter RF of a wireless communication system according to the present invention.

As shown in FIG. 2, the pulse mapper 520 of the integrated impulse generator of the transmitter RF 50 inputs n-bit data to be transmitted to one input terminal, and in this case, the other input terminal is fixed at 3.3V. And a latch 5201, an AND gate 5203 for mixing the output signal of the D latch, a signal obtained by delaying the output signal by a predetermined time, and an inverter 5205. If one input of the D latch 5201 is fixed at 3.3V and a data signal is applied to the other input, the D latch outputs an impulse signal whenever there is a data signal. The output signal is modulated by the AND gate 5203 and the signal delayed by a predetermined time (t), and outputs the signal in the ON-OFF-Keying manner through the inverter 5205. The impulse output from the pulse mapper 520 is converted through the band pass filter to meet the propagation law, and amplified and transmitted through the ultra wide band transmission antenna 60. Here, the two inputs of the D latch 5201 may be applied as data at the same time. With such a configuration, the conventional ON-OFF-Keying method can be more simply implemented, thereby reducing the cost and complexity of the entire system.

3A to 3D are diagrams illustrating a transmission module consisting of an ultra-wideband antenna and a transmitter RF of a system according to the present invention, and a form of an impulse detected therein.

FIG. 3A is a diagram illustrating a form in which a transmission module of a transmitter RF and an ultra wideband transmission antenna described above is printed on a printed board, FIG. 3B is a diagram illustrating an actual implementation form of the transmission module, and FIG. 3C is a transmission of the transmission module. (Tx) This diagram shows the shape of data output from the signal processor. As shown in FIG. 3C, a signal that has undergone ON-OFF keying is converted into RZ (Return to Zero). FIG. 3D is a diagram illustrating an impulse actually obtained when the signal of FIG. 3C passes through the bandpass filter. FIG.

4 is a diagram illustrating a configuration of a receiving RF of a wireless communication system according to the present invention.

As shown in FIG. 4, the receiver RF 20 includes a broadband band pass filter 210 for preventing interference of adjacent frequencies among signals received from an antenna, a low noise amplifier 220 for low noise amplification of the filtered signal, An active attenuator 223 for adjusting the size of the signal, an AGC (Automatic Gain Control) amplifier 226 for amplifying the signal, a two-stage envelope detector 230 for turning the amplified RF signal into a square pulse, Comparator 240 for converting the detected signal into a rectangular pulse. In the receiving RF, the modulated signal received from the receiving antenna 10 is amplified by 45dB in the low noise amplifier 220, and in the active attenuator 223, the signal waveform is unmodified and the amplitude is adjusted to 2 to 34dB. The amplified modulated signal is detected by the two-stage envelope detector 230 as an original signal and converted into a rectangular pulse. Components of the receiving RF are supplied with DC power, respectively, which causes a switching effect as the regulator 215 changes to 5V. The comparator 240 has a reference voltage of about 50mV and is designed to adjust the voltage level by a control signal. When the detected signal is input over the reference voltage for a predetermined time or more, the output produces a 3.3V square pulse output.

In more detail, when the impulse signal is converted into a rectangular pulse, the impulse signal emitted from the transmitter forms a multipath by various obstacles, and the actual received signal is received in a shape having a certain time delay as a superposition of single pulses. do. The received pulse is amplified by the low noise amplifier 220 and the AGC amplifier 226, passes through the envelope detector 230, the signal conversion is made through an integrator, and the signal integrated for a predetermined time is applied to the DC level detector of the next stage. The level is detected and the front end attenuator is adjusted to receive the appropriate input of comparator 240. Finally, a square wave signal is obtained through a comparator. Such a two stage envelope detector circuit and a comparator circuit using an integrator and an OP AMP are shown in FIG. 5. At this time, an envelope detector and a comparator may be further installed to increase the width of the square pulse signal and to reduce the influence of noise to obtain a clean waveform.

FIG. 6 is a diagram illustrating a rectangular pulse conversion process of an impulse signal in a receiving RF of a wireless communication system according to the present invention as shown in FIG. 4, and FIG. 7 is measured through a pulse conversion process as shown in FIG. 6. It is a figure which shows a rectangular impulse waveform graph.

8A is a diagram illustrating a configuration of a digital signal restoration unit using a high speed digital sampler of a wireless communication system according to the present invention.

The high-speed digital sampler structure delays the existing system clock by a little from the clock generator unit 310 having a time delay element so that the entire clock has a high clock. It consists of a pulse detector 320 for detecting the time interleaving time delay to the high clock clock by slightly delaying the existing system clock in the clock generator unit having a time delay element using a relatively low frequency system clock It can be called a structure. More specifically, the clock generator 310 may obtain a desired clock by using an inverter having a relatively accurate delay time as a delay device or by changing a phase of a clock of an existing system. First, using a system clock (Reference Clock) with a relatively low repetition frequency and a time delay or phase shift element, a plurality of clocks are generated that are equal to a system clock having a constant time difference (within the system clock period) / phase difference (within 360 degrees). In order to detect a signal such as an ultra-short rectangular pulse output from the comparator at the rising or falling time, a plurality of time delayed / phase-shifted system clocks are arranged in parallel. Signal detection units exist for a plurality of system clocks generated by the clock generator unit, which form a parallel structure. If a signal is detected by one or more signal detectors of the plurality of signal detectors, it is determined that data has been received. The clock generator unit is illustrated in detail in FIG. 8B. By using a plurality of delay lock loops (DLLs), a plurality of clocks having different phases are generated to enable high-speed sampling of short pulses.

The pulse detection signal processor 320 selects only the first clock among the detected time delay / phase delayed system clocks, and ignores the signal detected at the rising / falling edge of another clock for one period. The reason for choosing this approach is that the impulse propagation channel has a power delay profile of approximately 20 nanoseconds or more in a multipath environment, so that a high-speed digital sampler has at least two time delays for one signal during a period. Since the above clock will detect the impulse signal, it is necessary to forcibly recognize it as one signal.

The signal detected by the signal restorer using the high speed digital sampler is sequentially transmitted to a head / tail checker for checking at a predetermined interval of the reception (Rx) signal processor 410 and to a Viterbi decoder for forward error correction. do.

9A and 9B are diagrams illustrating signal detection clocks for the comparator output as shown in FIG. 8A.

9A is a timing diagram of signal detection by a high-speed clock made in parallel to the comparator output. If the pulse width of the received signal is T (T <impulse repetition period) and the conventional clock period is Ts, a delay time for signal detection is shown. With Ts / 4, three clocks having a phase difference of 90 degrees from the conventional clock are made in parallel, and each of them catches the received signal at the rising edge of the clock. At this time, in consideration of the response time of the digital element, the delay time should be less than or equal to 1/4 times the received signal pulse width in order to surely search for the signal. The signal detected in FIG. 8 to FIG. 9 searches for the signal in the first signal detector of FIG. 8A, and then discards all values input during one impulse period. The proposed signal reconstruction method can also be used in systems for position measurement, using impulses at close range. That is, unlike the conventional wireless positioning method using the A / D converter, the method proposed by the present invention generates a parallel clock having a performance of about GHz in the digital unit, and a rectangular pulse having a pulse width of several nanoseconds. Find the location of. In this case, the positioning resolution is related not only to the speed of the high speed digital sampler, but also to the width of the spherical pulse.

9B is a diagram illustrating a restoration process of a signal measured using a logic analyzer in an actual impulse communication system. The transmitted signal is a Return to Zero (RZ) signal, and the detected signal is a non-return to zero (NRZ) signal while the pulse width is much less than the transmit signal width.

10 is a diagram illustrating a transmission (Tx) signal processor of the system according to the present invention.

All transmission data is processed in real time by the transmission (Tx) signal processor. The transmission (Tx) signal processor 510 includes a memory 511 and a forward error correction encoder 512 capable of storing data. A Start & Stop signal generator 513 for notifying the start and end of actual data transmission, a mux (MUX) 515 for selecting actual data and control data, a memory 516 for storing data passing through the mux; Finally, it consists of a data mapper 517 that receives the data and creates the desired pulse train. The pulse string finally generated by the transmission (Tx) signal processor is sequentially transmitted to a pulse mapper 520 and a pulse shaper 530, which are integrated impulse generators, through the data mapper 517. The optimum pulse train can be created, resulting in a high signal-to-noise ratio. In addition, there are control signals for controlling the flow of the entire signal transmission in the transmission (Tx) signal processing unit 510, and changes in controlled states for applying control signals to each element constituting the transmission (Tx) signal processing unit. A controller (FSM) 514 that sequentially represents.

11 is a diagram illustrating a reception (Rx) signal processor of the system according to the present invention.

Like the transmission (Tx) signal processing unit, all received signals are processed in real time by the reception (Rx) signal processing unit. As shown in FIG. 13, the reception (Rx) signal processing unit 410 is received from the signal recovery unit. Start & Stop (Head & Tail) signal generator 411 for notifying the start and end of transmission so as to confirm the start and end of the frame of the actual digital signal recovered, a memory 412 for storing the transmitted data, A forward error correction decoder 413 for decoding the encoded data, and finally a memory 414 for storing the original data. In addition, there are control signals for controlling the flow of the entire signal transmission in the reception (Rx) signal processing unit 410, and changes in controlled states for applying control signals to each element constituting the reception (Rx) signal processing unit. A controller (FSM) 415 that sequentially represents is included.

12 is a flowchart illustrating a control process performed by a transmit (Tx) signal processor and a receive (Rx) signal processor of the system according to the present invention.

First, as shown in the control flowchart of the transmitter on the left side, in the transmitter RF 50 of the system according to the present invention, when data to be transmitted is generated during the transmission standby mode (S51) (S52), the start of the frame and the synchronization information first. After transmitting the start code including a (S53), the actual data is sent (S54), and finally, after transmitting the end code indicating the end of the frame, and switches back to the transmission standby mode (S55). On the other hand, referring to the receiving end control flow chart of the right side of Figure 12, the receiving end RF (20) according to the present invention, when receiving a start code (S21) of the receiving standby mode (S21) starts receiving data, otherwise the standby mode again Are switched to (S22, S23). If the end code is found during data reception, the data reception is completed and the signal is switched back to the standby mode. Otherwise, the data is returned to the state before the data reception (S24).

13 is a diagram illustrating an embodiment of a protocol in which data is transmitted in a system according to the present invention. The upper part of FIG. 13 is a data transmission protocol structure for the case of using the Pear-to-Pear method (one-to-one method), and the lower part shows a method of dividing and transmitting data in case of multiple users.

14 is a diagram illustrating an embodiment of an ultra-wideband antenna used in a system according to the present invention.

As shown in FIGS. 3A and 14, the antenna may use a flat monopole antenna printed in a step shape on a cross section of a printed board having an inclined inclined surface, and has an inclined ground to improve characteristics. . Preferably, the power supply uses a coplanar waveguide (CPW) structure, and a triangular or square transition portion is inserted into the power supply portion in the monopole antenna structure, which has a rectangular monopole antenna structure, to have broadband characteristics.

FIG. 15 is a graph showing a broadband antenna return loss that may be measured when using an ultra wideband antenna as shown in FIG. 14.

The reflection coefficient of an antenna is an index that simply calculates the reflection caused by the difference in impedance at a connection stage as the ratio of input voltage to reflection voltage, and this reflection coefficient is converted into a log scale (dB) of power. . The return loss value always has a minus sign at the dB value because the reflected power is smaller than the incoming power, and it is more convenient to evaluate it as a positive value without a sign. Convert to a value. Therefore, the larger the reflection loss value, the smaller the reflection. When looking at the characteristics of the antenna shown in FIG. 15, it appears that matching is well performed at a frequency of 5 GHz, thereby minimizing the occurrence of the reflection loss.

As described above, the short-range impulse asynchronous wireless communication system using the high-speed digital sampler according to the present invention has the effect of simplifying the transmitter system and reducing power consumption by using a method of simply converting data into an impulse signal at the transmitter. In addition, the receiver does not use a conventional high-speed A / D converter, but uses a high-speed digital sampler that restores a signal, thereby simplifying the entire system and performing signal detection on a digital unit to reduce power consumption. . In particular, by presenting a signal processing unit for the entire system, a short range wireless communication system having a real low speed, low power, low complexity system has been developed. Such a system can be used for home network home appliance control, sensor networks, low power UWB-RFID, and low to medium speed short range personal communication devices.

In the above described and illustrated with respect to the preferred embodiments of the present invention, the present invention is not limited to the specific embodiments described above, in the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims Various modifications can be made by those skilled in the art, and such changes are within the scope of the claims.

In the short-range impulse asynchronous wireless communication system using the high-speed digital sampler according to the present invention, when the conventional A / D converter is used, the complexity of the system is increased and power consumption is generated, resulting in a high price of the entire system and low complexity. And in order to solve the problem that it is difficult to implement a low-power system, by using a high-speed digital sampler to recover the signal, the entire system is simplified, and the signal detection in the digital unit is performed to reduce the power consumption.

In addition, by using the method of simply converting the data into an impulse signal at the transmitting end, the system has the effect of simplifying the transmitting system and reducing the power consumption, and presenting the signal processing unit for the whole system. A short range wireless communication system with a complexity system has been developed.

Such a system can be used for home network home appliance control, sensor networks, low power UWB-RFID, and low to medium speed short range personal communication devices.

Claims (15)

In a wireless communication system using an ultra wide band (UWB) impulse, A transmit RF including a transmit (Tx) signal processor, an integrated impulse generator capable of implementing a simple ON-OFF-Keying modulation scheme, and an amplifier for amplifying the impulse generator output; A receiver RF including a two stage envelope detector for detecting a received signal and a comparator for converting the detected signal into a rectangular pulse; A signal restoring unit using a high speed digital sampler for restoring a signal transmitted from the receiving end RF; A signal processing unit including a reception (Rx) signal processing unit for decoding the detected signal; And A near field impulse asynchronous wireless communication system using a high speed digital sampler, comprising an ultra wideband antenna for transmitting and receiving an ultra wideband signal. The method of claim 1, The high speed digital sampler includes a clock generator unit having a time delay element and a pulse detector for detecting a rectangular pulse. The clock generator unit generates a clock having a higher frequency than the system clock and applies the received clock to the received signal. A near field impulse asynchronous wireless communication system using a high speed digital sampler, characterized in that it detects a modulated received signal. The method of claim 2, Adding a time delay or phase shift element to the clock generator unit to generate at least one clock having a constant time difference or phase difference from the system clock, and to arrange the system clock and the generated at least one clock in parallel; A near field impulse asynchronous wireless communication system using a high speed digital sampler, characterized in that. The method of claim 1, The integrated impulse generator of the transmitting RF is an AND gate for mixing a D latch for inputting n-bit data to be transmitted to at least one input terminal, and an output signal of the D latch and a signal delaying the output signal by a predetermined time. And a short-range impulse asynchronous wireless communication system using a high-speed digital sampler, characterized in that it comprises an inverter. The method of claim 4, wherein In the input terminal of the D latch, when the data to be transmitted to one input terminal is applied, the other input terminal is fixed at 3.3V, so that an impulse signal is output from the D latch whenever there is a data signal. A near field impulse asynchronous wireless communication system using a high speed digital sampler. The method of claim 1, The receiver RF is a broadband band pass filter for preventing interference of adjacent frequencies among the signals received from the ultra-wideband antenna, a low noise amplifier for low noise amplification of the filtered signal, an active attenuator for controlling the size of the signal, signal amplification A near field impulse asynchronous wireless communication system using a high speed digital sampler, characterized in that the AGC (Automatic Gain Control) amplifier is connected to the two-stage envelope detector. The method of claim 6, A short-range impulse asynchronous wireless communication system using a high-speed digital sampler, characterized in that to obtain a square pulse by installing a second stage envelope detector and a comparator in the receiving RF. The method of claim 1, The transmission (Tx) signal processor may include a memory capable of storing data, a forward error correction encoder, a signal generator for generating a start & stop signal indicating start and end of actual data transmission, actual data and control data. Near-field impulse asynchronous using a high speed digital sampler, characterized in that consisting of a mux (MUX) to select, a memory for storing the data passed through the MUX, and a data mapper to finally receive the data to create a desired pulse train Wireless communication system. The method of claim 1, The receiving (Rx) signal processor is a Start / End signal generator for checking the start and end of the pulse train of the digital signal restored through the signal restorer, a memory for storing the actual data, decoding the encoded signal at the transmitter A forward error correction decoder, a short-range impulse asynchronous wireless communication system using a high-speed digital sampler, characterized in that consisting of a memory that finally stores the original data. The method according to claim 8 or 9, The signal processing unit includes a controller (FSM) for applying the control data to each device, in order to control the flow of the entire signal transmission short-range impulse asynchronous wireless communication system using a high-speed digital sampler. The method of claim 1, The ultra-wideband antenna is a rectangular monopole antenna printed stepwise on a cross section of a printed circuit board having an inclined surface, and has a short-range impulse asynchronous radio using a high-speed digital sampler, characterized in that it has a feed line of a CPW (coplanar waveguide) structure. Communication system. The method of claim 11, The ultra-wideband antenna is a short-range impulse asynchronous wireless communication system using a high-speed digital sampler, characterized in that for inserting a transition (triangle or square) in the feed section to have a broadband characteristics. delete delete In a high speed digital sampler constituting a wireless communication system using an ultra wide band (UWB) impulse, A clock generator unit for adding a time delay or phase shift element, generating at least one clock having a constant time difference or phase difference from a system clock, and arranging the system clock and the generated at least one clock in parallel; And And a pulse detector for applying the system clock and the at least one clock to a received signal to detect a modulated received signal.

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