CN100409597C - Pulse train optical transmission system and transmitter and receiver apparatuses used therein - Google Patents

Abstract

An optical transmission system for optically transmitting at least one data signal includes pulse train generating means for converting each of the at least one data signal respectively to a pulse train, based on at least one encoding pattern that is uniquely predetermined corresponding to the at least one data signal, and outputting the pulse train, optical modulating means for converting the pulse train output from the pulse train generating means to an optically modulated signal and outputting the signal, an optical transmission path for transmitting the optically modulated signal that is output from the optical modulating means, optical detecting means for converting the optically modulated signal transmitted on the optical transmission path to an electrical signal and outputting the signal, and data signal extracting means for obtaining the pulse train from the electrical signal that is output from the optical detecting means based on a decoding pattern that uniquely corresponds to the encoding pattern and extracting the data signal.

Description

Pulse train optical transmission system and use therein transmitter and receiver device

Technical field

The present invention relates to be used for the system and the use therein transmitter and receiver device of transmission burst.Particularly, the present invention relates to use the system and the use therein transmitter and receiver device of optical communication transmission burst.

Background technology

Figure 19 is the figure that the structure of the conventional transmission system of transmitting burst is shown.In Figure 19, the conventional transmission system comprises pulse train generation part 901, electrical transmission path 902, pulse train receiving unit 903 and demodulation part 904.Pulse train generation part 901 is connected by electrical transmission path 902 with pulse train receiving unit 903.Pulse train receiving unit 903 is connected with demodulation part 904 usefulness leads or without lead.

To the as above operation of the conventional transmission system of structure be described.Pulse train generation part 901 converts input data signal X to burst according to the predictive encoding figure, and it is sent to electrical transmission path 902.Pulse train receiving unit 903 is with respect to carrying out predetermined process by the burst of electrical transmission path 902 transmission, as amplifying and/or waveform shaping, and with lead or without lead treated burst sent to demodulation part 904.Use and the unique corresponding decoding figure of coded graphics demodulation part 904, demodulates original data signal X from the burst of doing predetermined process through pulse serial connection receiving portions 903, and extract it.

Aforesaid conventional transmission system for example can be applicable to use the wireless access system of the burst that is called UWB (ultra broadband) signal.The UWB signal is to have little one pole of width or bipolar base band pulse string.The UWB signal is the signal that frequency spectrum is expanded.Therefore, the peak power of UWB signal is suppressed.Therefore, can reduce interference level to other wireless signal.Owing to specify specific coding/decoding figure (burst), interfere steadiness thereby improve corresponding to each wireless terminal.Therefore, can be implemented in the wireless system of multiplexed a plurality of wireless signals in the identical frequency band.

For example, Japanese patent application publication No. 2001-308899 and 6-326723 are the conventional arts that is similar to above-mentioned conventional transmission system.

Yet for the short pulse signal such as the UWB signal, along with frequency band broadens, it is big that loss will become.Therefore, when general electric wire is used as transmission channel, the distance that short pulse signal can transmit will be very short.

Between the propagation periods in transmission channel, because such as the dependent influence of the transmission characteristic of group delay on the wideband frequency, transmitted waveform is with remarkable deterioration.Therefore, even increase the transmitted power of short pulse signal, transmission range also is limited.

Use the transmission system of short pulse signal to have the particular problem that these factors limit the coverage less.

Summary of the invention

Therefore, the purpose of this invention is to provide the transmission system of the wire transmission distance with amplification, wherein short pulse signal can not be subjected to the influence ground transmission of the characteristic of transmission channel, and use therein transmitter and receiver.

In order to realize above purpose, the present invention has following feature.A first aspect of the present invention relates to a kind of optical transmission system that is used at least one data-signal of optical transmission, it comprises burst generating device, be used for according to converting each of at least one data-signal to a pulse train respectively corresponding at least one unique predetermined coded graphics of at least one data-signal, and output pulse string; Optic modulating device is used at least one pulse train of burst generating device output is converted to light modulating signal and exports this signal; Optical transmission pathway is used to transmit the light modulating signal that optic modulating device is exported; Optical detection device, the light modulating signal that is used for transmitting on the optical transmission pathway convert the signal of telecommunication to and export this signal; The data signal extraction device is used for obtaining pulse train and extracting data-signal according to unique signal of telecommunication of exporting from optical detection device corresponding to the decoding figure of coded graphics.

Therefore, change transmission burst then, make it possible to provide the transmission system of the wire transmission distance with increase, wherein short pulse signal can not be subjected to the influence ground transmission of the characteristic of transmission channel.

For example, burst generating device converts a data-signal to pulse train.

Therefore, can realize optical communication one to one.

Preferably, burst generating device comprises pulse train generation part, be used for converting input data signal to pulse train and output pulse string according to the predictive encoding figure, optic modulating device comprises light modulation portion, be used for the pulse train that pulse train takes place partly to export is converted to light intensity modulated signal and exports this signal, optical detection device comprises the optical detection part branch, the light intensity modulated signal that is used for transmitting on the optical transmission pathway converts the signal of telecommunication once more to and exports this signal, the data signal extraction device comprises the demodulation part, is used for dividing the signal of telecommunication of output to extract pulse train and demodulated data signal according to unique decoding figure corresponding to coded graphics from optical detection part.

Therefore, convert data-signal to pulse train, convert light signal again to, carry out optical transmission then according to predetermined unique coded graphics corresponding to data-signal.Then, convert the light signal that receives to pulse train, from pulse train, demodulate data-signal according to unique decoding figure corresponding to coded graphics.Therefore, compare, can grow the Distance Transmission pulse train, and not be subjected to the influence of the characteristic of transmission channel with the transmission of pulse train in the electrical transmission path.

Preferably, burst generating device comprises pulse train generation part, be used for converting input data signal to pulse train and output pulse string according to the predictive encoding figure, optic modulating device comprises light modulation portion, be used for the pulse train that pulse train takes place partly to export is converted to light intensity modulated signal and exports this signal, optical detection device comprises the optical detection part branch, the light intensity modulated signal that is used for transmitting on the optical transmission pathway converts the signal of telecommunication once more to and exports this signal, the data signal extraction device comprises radiant section, be used for dividing the signal of telecommunication of output as the wireless signal radiation optical detection part, and wireless terminal, be used for extracting pulse train and demodulated data signal from the wireless signal of radiant section radiation according to unique decoding figure corresponding to coded graphics.

Therefore, the pulse train that takes place according to data-signal is converted into light signal and carries out optical transmission, then by radiation such as antennas.Therefore, can realize the optical transmission system of the long Distance Transmission of broadband wireless signal high-quality.

Preferably, burst generating device comprises pulse train generation part, be used for converting input data signal to pulse train and output pulse string according to the predictive encoding figure, optic modulating device comprises light modulation portion, be used for the pulse train that pulse train takes place partly to export is converted to light intensity modulated signal and exports this signal, optical transmission system also comprises the pulse compression part, be used to receive the light intensity modulated signal of transmission channel transmission, compression is as the pulse duration of the pulse train of modulation intelligence, or reduce the rise time and/or the fall time of pulse train, and output result, wherein optical detection device comprises the optical detection part branch, is used for the light signal that pulse compression is partly exported is converted to the signal of telecommunication and exports this signal.

Therefore, the pulse duration of the light signal after the optical transmission can reduce, thereby can relax the condition that pulse duration should reduce in transmitter installation.

Preferably, burst generating device comprises pulse train generation part, be used for converting input data signal to pulse train and output pulse string according to the predictive encoding figure, and filter segment, be used to increase the pulse duration that the pulse train of part output takes place pulse train, or the rise time and the fall time of increase pulse train, and output result, optic modulating device comprises light modulation portion, be used for the pulse train of filter segment output is converted to light intensity modulated signal and exports this signal, optical transmission system also comprises the pulse compression part, be used to receive the light intensity modulated signal of transmission channel transmission, compression is as the pulse duration of the pulse train of modulation intelligence, or reduce the rise time and/or the fall time of pulse train, and the output result, wherein optical detection device comprises the optical detection part branch, is used for the light signal that pulse compression is partly exported is converted to the signal of telecommunication and exports this signal.

Therefore, increasing and after optical transmission, reducing the pulse duration of transmission signals before the optical transmission, thereby in transmission signals, can relax the condition that pulse duration should reduce.

Preferably, burst generating device comprises pulse train generation part, be used for converting input data signal to pulse train and output pulse string according to the predictive encoding figure, optic modulating device comprises optic angle degree modulating part, be used for the pulse train that pulse train takes place partly to export is converted to optic angle degree modulation signal and exports this signal, optical detection device comprises interference of light part, be used to receive the optic angle degree modulation signal that transmits on the optical transmission pathway and detect relevant as between the phase ortho position of the pulse train of modulation intelligence, has polarity toward each other and corresponding to two equation of light sub-signals of the difference component of pulse train with output, with the optical detection part branch, one that is used for equation of light sub-signal that the interference of light is partly exported converts the signal of telecommunication to and exports this signal.

Therefore, can realize optical transmission system, and not increase burden transmitter installation and transmission channel with high quality and low cost mode transmission broadband signal.

For example, the interference of light partly comprises the beam split part, be used for input optic angle degree modulation signal is divided into two, the light delay part, be used to beam split partly cut apart and the optic angle degree modulation signal exported in one or two predetermined light delay amount is provided and exports the result, with light combination/beam split part, the optic angle degree modulation signal combination that another optic angle degree modulation signal that is used for beam split partly cut apart and exports and light delay are partly exported, and the result is divided into two once more, have the equation of light sub-signal of polarity toward each other with output.

Therefore, can simplify the structure of interference of light part.

Preferably, predetermined light delay amount is less than a bit width of pulse train.

Therefore, it is suitable that parameter that can interference of light system is set to, thereby can realize the photosystem with more high-quality transmission broadband signal.

Preferably, burst generating device comprises pulse train generation part, be used for converting input data signal to pulse train and output pulse string according to the predictive encoding figure, optic modulating device comprises optic angle degree modulating part, be used for the pulse train that pulse train takes place partly to export is converted to optic angle degree modulation signal and exports this signal, optical detection device comprises interference of light part, be used to receive the optic angle degree modulation signal that transmits on the optical transmission pathway and detect relevant as between the phase ortho position of the pulse train of modulation intelligence, has polarity toward each other and corresponding to two equation of light sub-signals of the difference component of pulse train with output, with the photo-equilibrium test section, be used for converting two equation of light sub-signals that the interference of light is partly exported to each signal of telecommunication once more, and make up two signals to produce and to export bipolar differential pulse string.

Therefore, can realize optical transmission system, and not increase burden transmitter installation and transmission channel with high-quality and low-cost mode transmission broadband signal.

For example, the interference of light partly comprises the beam split part, be used for input optic angle degree modulation signal is divided into two, the light delay part, be used to beam split partly cut apart and the optic angle degree modulation signal exported in one or two predetermined light delay amount is provided and exports the result, with light combination/beam split part, the optic angle degree modulation signal combination that another optic angle degree modulation signal that is used for beam split partly cut apart and exports and light delay are partly exported, and the result is divided into two once more, have the equation of light sub-signal of polarity toward each other with output.

Therefore, can simplify the structure of interference of light part.

Preferably, predetermined light delay amount is less than a bit width of pulse train.

Therefore, it is suitable that parameter that can interference of light system is set to, thereby can realize the photosystem with more high-quality transmission broadband signal.

For example, the photo-equilibrium test section comprises the first optical detection part branch, is used for first a differential pulse string that converts to once more as the signal of telecommunication of equation of light sub-signal that the interference of light is partly exported, and exports this signal; The second optical detection part branch, another equation of light sub-signal that is used for the interference of light is partly exported converts the second differential pulse string as the signal of telecommunication once more to, and exports this signal; Decay part is used to first optical detection part to divide the first differential pulse string of output and/or second optical detection part to divide the second differential pulse string of output that predetermined electric delay amount is provided, and the output result; And built-up section, be used for the first differential pulse string and the combination of the second differential pulse string, to export bipolar differential pulse string with decay part output.

Therefore, handle the bipolar burst of generation, thereby can realize optical transmission system, and do not increase burden transmitter installation, transmission channel and radiation appliance with high-quality and low-cost mode transmission broadband signal by light signal.

For example, the interference of light partly comprises the beam split part, be used for input optic angle degree modulation signal is divided into two, the light delay part, be used to beam split partly cut apart and the optic angle degree modulation signal exported in one or two predetermined light delay amount is provided and exports the result, with light combination/beam split part, the optic angle degree modulation signal combination that another optic angle degree modulation signal that is used for beam split partly cut apart and exports and light delay are partly exported, and the result is divided into two once more, has the equation of light sub-signal of polarity toward each other with output, wherein the photo-equilibrium test section comprises the first optical detection part branch, be used for first a differential pulse string that converts to once more as the signal of telecommunication of equation of light sub-signal that the interference of light is partly exported, and export this signal; The second optical detection part branch, another equation of light sub-signal that is used for the interference of light is partly exported converts the second differential pulse string as the signal of telecommunication once more to, and exports this signal; Decay part is used to first optical detection part to divide the first differential pulse string of output and/or second optical detection part to divide the second differential pulse string of output that predetermined electric delay amount is provided, and the output result; And built-up section, be used for the first differential pulse string and the combination of the second differential pulse string, to export bipolar differential pulse string with decay part output.

Therefore, can simplify the structure of interference of light part and photo-equilibrium test section.

Preferably, predetermined electric delay amount equals predetermined light delay amount.

Therefore, it is suitable that parameter that can optical detection system is set to, thereby can realize with the photosystem of mode transmission broadband signal more cheaply.

Preferably, burst generating device comprises pulse train generation part, be used for converting input data signal to pulse train and output pulse string according to the predictive encoding figure, optic modulating device comprises light modulation portion, be used for the pulse train that pulse train takes place partly to export is converted to light intensity modulated signal and exports this signal, optical transmission system also comprises the wavelength dispersion part, it has wavelength dispersion characteristics and receives the light intensity modulated signal that transmits on the optical transmission pathway, compression is as the pulse duration of the pulse train or the composite signal of modulation intelligence, or reduce the rise time and/or the fall time of pulse train, and output result, wherein optical detection device comprises the optical detection part branch, is used for the light signal that wavelength dispersion is partly exported is converted to the signal of telecommunication and exports this signal.

Therefore, can utilize the non-linear pulse duration that reduces light signal of optical fiber, thereby can realize transmitting and do not use the optical transmission system of particular device with high-quality and low-cost mode.

Preferably, light modulation portion is used the direct sunshine modulation scheme, wherein injects the electric current of semiconductor laser with the modulation of input pulse string, with the output light intensity modulation signal.

Therefore, direct modulating system can be used as light modulation system to realize optical transmission system more cheaply.

For example, burst generating device converts at least two data-signals to pulse train.

Therefore, can realize the multiplexing of data-signal.

Preferably, burst generating device comprises a plurality of pulse train generation parts, be used for predetermined a plurality of data-signals being converted to each pulse train with predetermined modulation type corresponding to input data signal and the coded graphics that differs from one another according to each, and output pulse string, wherein optic modulating device comprises a plurality of light modulation portion that part takes place corresponding to pulse train, be used for the pulse train that each pulse train takes place partly to export is converted to each light modulating signal and exports these signals, with the light built-up section, be used to make up the light modulating signal of a plurality of light modulation portion outputs and output results to optical transmission pathway.

Therefore, the pulse train that is produced by the specific coding figure of data-signal is converted into light signal, is combined and carries out optical transmission.After this, optionally demodulation desired data signal, and extract with specific decoding figure.Therefore, can realize holding the optical transmission system of a plurality of data-signals with high-quality and simple mode.

Preferably, optical detection device comprises the optical detection part branch, the light modulating signal that is used for transmitting on the optical transmission pathway converts the signal of telecommunication once more to and exports this signal, the data signal extraction device comprises demodulation/separating part, is used for dividing the signal of telecommunication of output to extract pulse train and this data-signal of demodulation according to unique decoding figure corresponding to a plurality of coded graphicss from optical detection part.

Therefore, the pulse train that is produced by the specific separately coded graphics of a plurality of data-signals is converted into light signal, is combined and carries out optical transmission.After this, optionally demodulation desired data signal, and use decoding figure to extract corresponding to coded graphics.Therefore, can realize with the optical transmission system of high-quality with the simple multiplexed a plurality of data-signals of mode.

Preferably, optical detection device comprises the beam split part, the light modulating signal that is used for transmitting on the optical transmission pathway is divided into a plurality of signals and exports these signals, with a plurality of optical detection part branches, they correspond respectively to a plurality of light modulating signals that beam split is partly cut apart and exported, and convert light modulating signal to the signal of telecommunication once more to export this signal, the data signal extraction device comprises a plurality of demodulation/separating parts, they correspond respectively to a plurality of optical detection part branches, are used for dividing the signal of telecommunication of output to extract pulse train and this data-signal of demodulation according to unique decoding figure corresponding to a plurality of coded graphicss from optical detection part.

Therefore, the pulse train that is produced by the specific separately coded graphics of a plurality of data-signals is converted into light signal, is combined and carries out optical transmission.After this, in each signal that receives that is decomposed by the light multichannel, the data-signal of demodulation correspondence, and use decoding figure to extract corresponding to coded graphics.Therefore, can realize carrying out the optical transmission system of the multiplexed transmission of a plurality of data-signals with high-quality and simple mode.

Preferably, optical transmission system also comprises the data light modulating part, be used for data-signal is converted to light modulating signal and exports this signal, this data-signal has the speed of the repetition period of the pulse train that is lower than the output of a plurality of pulse trains generation part, the light built-up section is the data-signal of data splitting light modulation portion output also, the data signal extraction device comprises the data separating part, be used for the signal of telecommunication of optical detection part branch output is separated into data-signal and other signal (hereinafter being called " composite signal ") of the speed with the repetition period that is lower than pulse train, and modulation/separating part, be used for extracting pulse train and this data-signal of demodulation according to unique composite signal of partly exporting from data separating corresponding to the decoding figure of a plurality of coded graphicss.

Therefore, a plurality of data-signals are converted into pulse train, by multiplexed and carry out optical transmission, the data-signal that has the repetition period that is lower than pulse train simultaneously is by multiplexed, thereby can realize carrying out the optical transmission system of the multiplexed transmission of a plurality of data-signals in simple mode.

Preferably, optical transmission system also comprises the wavelength control part that is used to control, and makes the wavelength of the light modulating signal that a plurality of light modulation portion are exported not overlap each other.

Therefore, a plurality of data-signals are converted into pulse train, and are converted into light modulating signal, and light modulating signal is combined and carries out optical transmission, optionally separate then to be in harmonious proportion and extract the desired data signal, and suitably control the wavelength of light modulating signal.Therefore, can prevent because the quality deterioration that causes of interference between the light modulating signal, and can be with high-quality multiplexed and hold a plurality of data-signals.

Preferably, burst generating device comprises a plurality of input pulse string generation parts, be used for predetermined a plurality of data-signals being converted to each pulse train with predetermined modulation type corresponding to input data signal and the coded graphics that differs from one another according to each, and output pulse string, wherein optic modulating device comprises composite part, be used to export the signal of telecommunication that the pulse train acquisition of part output takes place by synthetic a plurality of pulse trains, and light modulation portion, be used for the electrical signal conversion of composite part output is become light modulating signal and exports this signal.

Therefore, synthetic also optical transmission is by the pulse train of the specific coding figure generation of data-signal.Therefore, optionally demodulation desired data signal, and extract with specific decoding figure.Therefore, can realize holding the optical transmission system of a plurality of data-signals with high-quality and simple mode.

Preferably, optical detection device comprises the optical detection part branch, and the light modulating signal that is used for transmitting on the optical transmission pathway converts the signal of telecommunication once more to and exports this signal.The data signal extraction device comprises demodulation/separating part, is used for dividing the signal of telecommunication of output to extract pulse train and this data-signal of demodulation according to unique decoding figure corresponding to a plurality of coded graphicss from optical detection part.

Therefore, synthetic also optical transmission is by the pulse train of the specific coding figure generation of a plurality of data-signals.Therefore, optionally demodulation desired data signal, and use decoding figure to extract corresponding to coded graphics.Therefore, can realize with the optical transmission system of high-quality with the simple multiplexed a plurality of data-signals of mode.

Preferably, optical detection device comprises the optical detection part branch, and the light modulating signal that is used for transmitting on the optical transmission pathway converts the signal of telecommunication once more to and exports this signal.The data signal extraction device comprises radiant section, is used for dividing the signal of telecommunication of output as the wireless signal radiation optical detection part; With a plurality of wireless terminals, be used for extracting pulse train and demodulated data signal from the wireless signal of radiant section radiation according to unique decoding figure corresponding to a plurality of coded graphicss.

Therefore, a plurality of pulse trains that produce according to a plurality of data-signals are combined, and are converted into light signal and carry out optical transmission, then by radiation such as antennas.Therefore, can realize carrying out the optical transmission system of the multiplexed transmission of a plurality of broadband wireless signals with high-quality.

Preferably, optical detection device comprises the beam split part, the light modulating signal that is used for transmitting on the optical transmission pathway is divided into a plurality of signals and exports these signals, with a plurality of optical detection part branches, they correspond respectively to a plurality of light modulating signals that beam split is partly cut apart and exported, and convert light modulating signal to the signal of telecommunication once more to export these signals, wherein the data signal extraction device comprises a plurality of demodulation/separating parts, they correspond respectively to a plurality of optical detection part branches, are used for dividing the signal of telecommunication of output to extract pulse train and demodulated data signal according to unique decoding figure corresponding to a plurality of coded graphicss from optical detection part.

Therefore, the pulse train that is produced by the specific separately coded graphics of a plurality of data-signals is synthesized, and is decomposed by the light multichannel.After this, in each signal that receives that is decomposed by the light multichannel, the data-signal of demodulation correspondence, and according to the decoding figure extraction corresponding to coded graphics.Therefore, can realize carrying out the optical transmission system of the multiplexed transmission of a plurality of data-signals with high-quality and simple mode.

Preferably, composite part also synthesizes the data-signal of the speed of the repetition period with the pulse train that is lower than the output of a plurality of pulse trains generation part, wherein optical detection device comprises the beam split part, the light modulating signal that is used for transmitting on the optical transmission pathway is divided into a plurality of signals and exports these signals, a plurality of optical detection part branches, they correspond respectively to a plurality of light modulating signals that beam split is partly cut apart and exported, and convert light modulating signal to the signal of telecommunication once more to export these signals, with the data light test section, one of the light modulating signal that is used for beam split partly cut apart and exports convert to once more have be lower than a plurality of pulse trains take place part output pulse train repetition period speed data-signal and export this signal, wherein the data signal extraction device comprises a plurality of demodulation/separating parts, they correspond respectively to a plurality of optical detection part branches, are used for dividing the signal of telecommunication of output to extract pulse train and demodulated data signal according to unique decoding figure corresponding to a plurality of coded graphicss from optical detection part.

Therefore, a plurality of data-signals are converted into each pulse train and by multiplexed, the data-signal that has the repetition period that is lower than pulse train simultaneously is by multiplexed and carry out optical transmission, thereby can realize carrying out the optical transmission system of the multiplexed transmission of a plurality of data-signals in simple mode.

Preferably, optical transmission system also comprises the pulse compression part, be used to receive the light intensity modulated signal that transmits on the transmission channel, compression is as the pulse duration of the pulse train of modulation intelligence, or reduce the rise time and/or the fall time of pulse train, and the output result, wherein optical detection device comprises the optical detection part branch, is used for the light signal that pulse compression is partly exported is converted to the signal of telecommunication and exports this signal.

Therefore, reduced the pulse duration of the light signal after the optical transmission, thus can realize curb transmitter device and transmission channel broadband character influence and carry out the optical transmission system of the multiplexed transmission of a plurality of broadband wireless signals with high-quality.

Preferably, optical transmission system also comprises filter segment, it becomes part corresponding to each pulse train generating unit division and combination, and the pulse duration of the pulse train of part output takes place in the increase pulse train, or the rise time and the fall time of increase pulse train, and output result, with the pulse compression part, be used to receive the light intensity modulated signal that transmits on the transmission channel, compression is as the pulse duration of the pulse train of modulation intelligence, or reduces the rise time and/or the fall time of pulse train, and the output result, wherein optical detection device comprises the optical detection part branch, is used for the light signal that pulse compression is partly exported is converted to the signal of telecommunication and exports this signal.

Therefore, in the pulse duration that increases and after optical transmission, reduce transmission signals before the optical transmission, thus can realize curb transmitter device and transmission channel broadband character influence and with the optical transmission system of the multiplexed transmission of a plurality of broadband wireless signals of more low-cost execution.

Preferably, light modulation portion is an optic angle degree modulating part, be used for the pulse train that pulse train takes place partly to export is converted to optic angle degree modulation signal and exports this signal, optical detection device comprises interference of light part, be used to receive the optic angle degree modulation signal that transmits on the optical transmission pathway and detect relevant as between the phase ortho position of the pulse train of modulation intelligence, has polarity toward each other and corresponding to two equation of light sub-signals of the difference component of pulse train with output, with the optical detection part branch, one that is used for equation of light sub-signal that the interference of light is partly exported converts the signal of telecommunication to and exports this signal.

Therefore, can realize carrying out the optical transmission system of the multiplexed transmission of broadband wireless signal, and not increase burden transmitter installation and transmission channel in the high quality and low cost mode.

For example, the interference of light partly comprises the beam split part, be used for input optic angle degree modulation signal is divided into two, the light delay part, be used to beam split partly cut apart and the optic angle degree modulation signal exported in one or two predetermined light delay amount is provided and exports the result, with light combination/beam split part, the optic angle degree modulation signal combination that another optic angle degree modulation signal that is used for beam split partly cut apart and exports and light delay are partly exported, and the result is divided into two once more, have the equation of light sub-signal of polarity toward each other with output.

Therefore, can simplify the structure of interference of light part.

Preferably, predetermined light delay amount is less than a bit width of pulse train.

Therefore, it is suitable that parameter that can interference of light system is set to, thereby can realize the photosystem with more high-quality transmission broadband signal.

Preferably, light modulation portion is an optic angle degree modulating part, be used for the pulse train that pulse train takes place partly to export is converted to optic angle degree modulation signal and exports this signal, optical detection device comprises interference of light part, be used to receive the optic angle degree modulation signal that transmits on the optical transmission pathway and detect relevant as between the phase ortho position of the pulse train of modulation intelligence, has polarity toward each other and corresponding to two equation of light sub-signals of the difference component of pulse train with output, with the photo-equilibrium test section, be used for converting two equation of light sub-signals that the interference of light is partly exported to each signal of telecommunication once more, and make up two signals to produce and to export bipolar differential pulse string.

Therefore, can realize carrying out the more optical transmission system of the multiplexed transmission of bandwidth signals, and not increase burden transmitter installation and transmission channel with high-quality and low-cost mode.

For example, the interference of light partly comprises the beam split part, be used for input optic angle degree modulation signal is divided into two, the light delay part, be used to beam split partly cut apart and the optic angle degree modulation signal exported in one or two predetermined light delay amount is provided and exports the result, with light combination/beam split part, the optic angle degree modulation signal combination that another optic angle degree modulation signal that is used for beam split partly cut apart and exports and light delay are partly exported, and the result is divided into two once more, have the equation of light sub-signal of polarity toward each other with output.

Therefore, can simplify the structure of interference of light part.

Preferably, predetermined light delay amount is less than a bit width of pulse train.

Therefore, it is suitable that parameter that can interference of light system is set to, thereby can realize carrying out photosystem than the multiplexed transmission of bandwidth signals with high-quality more.

For example, the photo-equilibrium test section comprises the first optical detection part branch, is used for first a differential pulse string that converts to once more as the signal of telecommunication of equation of light sub-signal that the interference of light is partly exported, and exports this signal; The second optical detection part branch, another equation of light sub-signal that is used for the interference of light is partly exported converts the second differential pulse string as the signal of telecommunication once more to, and exports this signal; Decay part is used to first optical detection part to divide the first differential pulse string of output and/or second optical detection part to divide the second differential pulse string of output that predetermined electric delay amount is provided, and the output result; And built-up section, be used for the first differential pulse string and the combination of the second differential pulse string, to export bipolar differential pulse string with decay part output.

Therefore, handle the bipolar burst of generation by light signal, thereby can realize with higher quality and cheaply mode carry out the more optical transmission system of the multiplexed transmission of bandwidth signals, and do not increase burden to transmitter installation, transmission channel and radiation appliance.

For example, the interference of light partly comprises the beam split part, be used for input optic angle degree modulation signal is divided into two, the light delay part, be used to beam split partly cut apart and the optic angle degree modulation signal exported in one or two predetermined light delay amount is provided and exports the result, with light combination/beam split part, the optic angle degree modulation signal combination that another optic angle degree modulation signal that is used for beam split partly cut apart and exports and light delay are partly exported, and the result is divided into two once more, has the equation of light sub-signal of polarity toward each other with output, wherein the photo-equilibrium test section comprises the first optical detection part branch, be used for first a differential pulse string that converts to once more as the signal of telecommunication of equation of light sub-signal that the interference of light is partly exported, and export this signal; The second optical detection part branch, another equation of light sub-signal that is used for the interference of light is partly exported converts the second differential pulse string as the signal of telecommunication once more to, and exports this signal; Decay part is used to first optical detection part to divide the first differential pulse string of output and/or second optical detection part to divide the second differential pulse string of output that predetermined electric delay amount is provided, and the output result; And built-up section, be used for the first differential pulse string and the combination of the second differential pulse string, to export bipolar differential pulse string with decay part output.

Therefore, can simplify the structure of interference of light part and photo-equilibrium test section.

Preferably, predetermined electric delay amount equals predetermined light delay amount.

Therefore, it is suitable that parameter that can optical detection system is set to, thereby can realize carrying out the more photosystem of the multiplexed transmission of bandwidth signals in mode more cheaply.

Preferably, light modulation portion converts the pulse train that part output takes place pulse train light intensity modulated signal to and exports this signal, optical transmission system also comprises the wavelength dispersion part, it has wavelength dispersion characteristics and receives the light intensity modulated signal that transmits on the optical transmission pathway, compression is as the pulse duration of the pulse train or the composite signal of modulation intelligence, or reduce the rise time and/or the fall time of pulse train, and output result, wherein optical detection device comprises the optical detection part branch, is used for the light signal that wavelength dispersion is partly exported is converted to the signal of telecommunication and exports this signal.

Therefore, can utilize the non-linear pulse duration that reduces light signal of optical fiber, thereby can realize carrying out multiplexed transmission and do not use the optical transmission system of particular device with high-quality and low-cost mode.

Preferably, light modulation portion is used the direct sunshine modulation scheme, wherein injects the electric current of semiconductor laser with the modulation of input pulse string, with the output light intensity modulation signal.

Therefore, by direct modulating system can be realized carrying out at low cost the optical transmission system of the multiplexed transmission of a plurality of broadband wireless signals as light modulation system.

Preferably, the modulation type of the pulse train of burst generating device conversion is the pulse position modulation type.

Preferably, the pulse train of data signal extraction device acquisition is UWB (ultra broadband) signal.

Therefore, by using the position modulation type or the UWB signal of pulse train, can realize the optical transmission system of available bandwidth signal transmission of large capacity data.

A second aspect of the present invention relates to the transmitter installation of at least one data-signal of optical transmission, comprise burst generating device, be used for converting each of at least one data-signal to pulse train respectively, and export this pulse train according to unique predetermined at least one coded graphics corresponding at least one data-signal; And optic modulating device, be used at least one pulse train of burst generating device output is converted to light modulating signal and this signal is outputed to optical transmission pathway.

A third aspect of the present invention relates to and is used for receiving receiver apparatus with the light modulating signal of pulse train modulation by optical transmission pathway, this pulse train is by predetermined change at least one data-signal corresponding at least one coded graphics of at least one data-signal and obtain according to unique, this receiver apparatus comprises optical detection device, the light modulating signal that is used for transmitting on the optical transmission pathway converts the signal of telecommunication to, and exports this signal; With the data signal extraction device, be used for obtaining pulse train, and extract this data-signal according to unique signal of telecommunication of exporting from optical detection device corresponding to the decoding figure of coded graphics.

Description of drawings

Fig. 1 is the figure that transmission system 1 structure of first embodiment of the invention is shown.

Fig. 2 is the figure that transmission system 2 structures of second embodiment of the invention are shown.

Fig. 3 A is the figure that transmission system 3 structures of third embodiment of the invention are shown.

Fig. 3 B is the figure that the time waveform of the light modulating signal (a) that transmits on the pulse train (a) of pulse train generation part 111 output and the optical transmission pathway 200 is shown.

Fig. 3 C illustrates the figure of time waveform that pulse compression part 321 and optical detection part divide the pulse trains (b) of 301 outputs.

Fig. 4 A is the figure that transmission system 4 structures of fourth embodiment of the invention are shown.

Fig. 4 B illustrates pulse train the partly figure of the time waveform of the pulse train (a) of output takes place.

Fig. 4 C is the figure that the time waveform of the modulation signal (b) that transmits on the signal of telecommunication (b) of filter segment output and the optical transmission pathway 200 is shown.

Fig. 4 D illustrates the figure of time waveform that pulse compression part 321 and optical detection part divide the pulse trains (c) of 301 outputs.

Fig. 5 A is the figure that transmission system 5 structures of fifth embodiment of the invention are shown.

Fig. 5 B is the figure that the time waveform of the optic angle degree modulation signal (a) that transmits on the pulse train (a) of pulse train generation part 132 output and the optical transmission pathway is shown.

Fig. 5 C is the figure of the time waveform of the light signal (b) exported of light signal that beam split part 331 output is shown (a ') and light delay part 332.

Fig. 5 D is the figure that two equation of light sub-signals (c) and time waveform (d) are shown.

Fig. 6 A is the figure that transmission system 6 structures of sixth embodiment of the invention are shown.

Fig. 6 B is the figure that the time waveform of the optic angle degree modulation signal (a) that transmits on the pulse train (a) of pulse train generation part 132 output and the optical transmission pathway 200 is shown.

Fig. 6 C is the figure of the time waveform of the light signal (b) exported of light signal that beam split part 331 output is shown (a ') and light delay part 332.

Fig. 6 D is the figure that the time waveform of the first differential pulse string (c) and the second differential pulse string (d) is shown.

Fig. 6 E is the figure that the time waveform of the first differential pulse string (c) that is input to built-up section 345 and the second differential pulse string (e) is shown.

Fig. 6 F is the figure of time waveform that the bipolar differential pulse string (f) of built-up section 345 output is shown.

Fig. 7 is the figure that transmission system 7 structures of seventh embodiment of the invention are shown.

Fig. 8 is the figure that transmission system 8 structures of eighth embodiment of the invention are shown.

Fig. 9 is the figure that transmission system 9 structures of ninth embodiment of the invention are shown.

Figure 10 is the figure that transmission system 10 structures of tenth embodiment of the invention are shown.

Figure 11 is the figure that transmission system 11 structures of eleventh embodiment of the invention are shown.

Figure 12 is the figure that transmission system 12 structures of twelveth embodiment of the invention are shown.

Figure 13 is the figure that transmission system 13 structures of thriteenth embodiment of the invention are shown.

Figure 14 is the figure that transmission system 14 structures of fourteenth embodiment of the invention are shown.

Figure 15 A is the figure that transmission system 15 structures of fifteenth embodiment of the invention are shown.

Figure 15 B is the figure that the time waveform of the light modulating signal (a) that transmits on the pulse train (a) of the first and second pulse train generation parts 501,502 output and the optical transmission pathway 200 is shown.

Figure 15 C illustrates the figure of time waveform that pulse compression part 321 and optical detection part divide the pulse trains (b) of 301 outputs.

Figure 16 A is the figure that transmission system 16 structures of sixteenth embodiment of the invention are shown.

Figure 16 B is the figure of time waveform that the pulse train (a) of the first and second pulse train generation parts 141,142 output is shown.

Figure 16 C is the figure that the time waveform of the light modulating signal (b) that transmits on the signal (b) of filter segment 511,512 output and the optical transmission pathway 200 is shown.

Figure 16 D illustrates the figure of time waveform that pulse compression part 321 and optical detection part divide the pulse trains (b) of 301 outputs.

Figure 17 A is the figure that transmission system 17 structures of seventeenth embodiment of the invention are shown.

Figure 17 B is the figure that the time waveform of the light modulating signal (a) that transmits on the pulse train (a) of the first and second pulse train generation parts 521,522 and composite part 161 outputs and the optical transmission pathway 200 is shown.

Figure 17 C is the figure of the time waveform of the light signal (b) exported of light signal that beam split part 331 output is shown (a ') and light delay part 332.

Figure 17 D is the figure that two equation of light sub-signals (c) and time waveform (d) are shown.

Figure 18 A is the figure that transmission system 18 structures of eighteenth embodiment of the invention are shown.

Figure 18 B is the figure that the time waveform of the optic angle degree modulation signal (a) that transmits on the pulse train (a) of the first and second pulse train generation parts 521,522 and composite part 161 outputs and the optical transmission pathway 200 is shown.

Figure 18 C is the figure of the time waveform of the light signal (b) exported of light signal that beam split part 331 output is shown (a ') and light delay part 332.

Figure 18 D is the figure that the time waveform of the first differential pulse string (c) and the second differential pulse string (d) is shown.

Figure 18 E is the figure that the time waveform of the first differential pulse string (c) that is input to built-up section 345 and the second differential pulse string (e) is shown.

Figure 18 F is the figure of time waveform that the bipolar differential pulse string (f) of built-up section 345 output is shown.

Figure 19 is the figure that the structure of the conventional transmission system of transmitting burst is shown.

Embodiment

(first embodiment)

Fig. 1 is the figure that transmission system 1 structure of first embodiment of the invention is shown.In Fig. 1,, the time waveform of signal in the relative section is shown for the ease of understanding.In Fig. 1, transmission system 1 comprises transmitter installation 100, optical transmission pathway 200 and receiver apparatus 300.Transmitter installation 100 is connected by optical transmission pathway 200 with receiver apparatus 300.Transmitter installation 100 comprises pulse train generation part 101 and light modulation portion 102.Receiver apparatus 300 comprises that optical detection part divides 301 and demodulation part 302.

Then, will the operation of transmission system 1 be described.Data-signal D is input to pulse train generation part 101.Pulse train generation part 101 converts data-signal D pulse train to and exports it according to the predictive encoding figure.Light modulation portion 102 converts the pulse train of pulse train generation part 101 outputs to light intensity modulated signal, and it is sent to optical transmission pathway 200.Optical detection part divides 301 to have square detection characteristic, and it converts the light intensity modulated signal of optical transmission pathway 200 transmission the signal of telecommunication to and export it.Demodulation part 302 is used unique decoding figure corresponding to the coded graphics that uses in the pulse train generation part 101 to divide 301 signals of telecommunication of exporting from optical detection part and is extracted pulse train, and demodulated data signal D.

The modulation type of the pulse train that uses in the pulse train generation part 101 is the pulse position modulation type, wherein converts data-signal to pulse position information according to predetermined coded graphics corresponding to data-signal.Pulse train generation part 101 further reduces the pulse duration of pulse train, with spread spectrum to the frequency band of broad, power peak that therefore can the suppressor pulse string.Therefore, can reduce to influence the interference level of other pulse train.In addition, by specifying specific coding/decoding figure, can improve the interference steadiness corresponding to each data-signal.Particularly, can be with the UWB signal as pulse train.

Therefore, according to first embodiment, convert data-signal to pulse train according to predetermined unique coded graphics corresponding to data-signal, and convert it to light signal, carry out optical transmission then, convert the light signal that receives to pulse train, according to unique decoding figure demodulated data signal from pulse train corresponding to coded graphics.Therefore, compare, can grow the Distance Transmission pulse train, and not be subjected to the influence of the characteristic of transmission channel with the transmission of pulse train in the electrical transmission path.

(second embodiment)

Fig. 2 is the figure that transmission system 2 structures of second embodiment of the invention are shown.In Fig. 2,, the time waveform of signal in the relative section is shown for the ease of understanding.In Fig. 2, transmission system 2 comprises transmitter installation 100, optical transmission pathway 200, receiver apparatus 310 and wireless terminal 400.Transmitter installation 100 is connected by optical transmission pathway 200 with receiver apparatus 310.Transmitter installation 100 comprises pulse train generation part 101 and light modulation portion 102.Receiver apparatus 310 comprises that optical detection part divides 301 and radiant section 312.In Fig. 2, have identical drawing reference numeral with the frame that has identical function among first embodiment, will omit description of them.

Then, will the operation of transmission system 2 be described.Therefore the structure of this embodiment is similar to the structure (referring to Fig. 1) among above-mentioned first embodiment, only describes different aspects below.Radiant section 312 will via optical detection part divide 301 electrical signal converted convert to wireless signal and radiation it.The wireless signal of wireless terminal 400 receiver radiations, and use unique decoding figure to convert the wireless signal that receives to the signal of telecommunication corresponding to the coded graphics that uses in the pulse train generation part 101, to extract data-signal D.

Therefore, according to second embodiment, convert data-signal to pulse train according to predetermined unique coded graphics corresponding to data-signal, and convert it to light signal, carry out optical transmission then, convert the light signal that receives to pulse train, and with it therefore as the wireless signal radiation, according to unique decoding figure demodulated data signal from wireless signal corresponding to coded graphics.Therefore, compare, can grow the Distance Transmission pulse train, and not be subjected to the influence of the characteristic of transmission channel with the transmission of pulse train in the electrical transmission path.

(the 3rd embodiment)

Fig. 3 A is the figure that transmission system 3 structures of third embodiment of the invention are shown.In Fig. 3 A, transmission system 3 comprises transmitter installation 110, optical transmission pathway 200, receiver apparatus 320 and wireless terminal 400.Transmitter installation 110 is connected by optical transmission pathway 200 with receiver apparatus 320.Transmitter installation 110 comprises pulse train generation part 111 and light modulation portion 102.Receiver apparatus 320 comprises that pulse compression part 321, optical detection part divide 301 and radiant section 312.In Fig. 3 A, have identical drawing reference numeral with the frame that has identical function among first or second embodiment, will omit description of them.

Then, will the operation of transmission system 3 be described.Therefore the structure of this embodiment is similar to the structure (referring to Fig. 1 and 2) among above-mentioned first and second embodiment, only describes different aspects below.

Pulse train generation part 111 uses predetermined coded graphics that input data signal D is converted to pulse train and exports it.The pulse train of pulse train generation part 101 outputs is square pulse strings among first embodiment, and wherein its rising part and its sloping portion are significant sharp shape (staged).Yet the pulse train of pulse train generation part 111 outputs is that its rising part and sloping portion are certain pulse train that relaxes slope, and it is different from the pulse train among first embodiment.Hereinafter, this pulse is called " trapezoidal pulse ".Fig. 3 B is the figure that the time waveform of the light modulating signal (a) that transmits on the pulse train (a) of pulse train generation part 111 output and the optical transmission pathway 200 is shown.Shown in Fig. 3 B, the light modulating signal (a) of transmission is a trapezoidal pulse on the pulse train (a) of pulse train generation part 111 outputs and the optical transmission pathway 200.

Light modulation portion 102 converts the pulse train of pulse train generation part 111 outputs to light intensity modulated signal, and it is sent to optical transmission pathway 200.The light modulating signal that pulse compression part 321 receives through optical transmission pathway 200 transmission, and compress its modulation intelligence (pulse duration), promptly reduce the rise time and/or the fall time of modulation intelligence, and export it.Fig. 3 C illustrates the figure of time waveform that pulse compression part 32 1 and optical detection part divide the pulse trains (b) of 301 outputs.Shown in Fig. 3 C, it is square pulses that its pulse duration is reduced that pulse compression part 321 and optical detection part divide the pulse train (b) of 301 outputs.

For pulse compression part 321, for example can use common carrier, as monomode fiber with wavelength dispersion characteristics.For light modulation portion 102, use the direct sunshine modulation scheme, wherein directly modulate the electric current that injects semiconductor laser.That is to say, reciprocation between the wavelength dispersion in the light intensity modulated signal that character (wavelength acutance) that pulse compression part 321 use optical frequencies (wavelength) change and direct sunshine modulation scheme produce is compressed modulation intelligence, thereby has reduced the pulse duration that optical detection part divides the pulse trains of 301 outputs.

Therefore, according to the 3rd embodiment, handle the pulse duration that has reduced transmission signals by using optical transmission light signal afterwards.Therefore, can amplify the frequency spectrum of pulse train, and not increase transmitter installation and the necessary bandwidth of transmission channel, therefore can increase the interference steadiness.

In the 3rd embodiment, described from radiant section 312 radiation wireless signals and the system that wireless terminal, carries out demodulation.Yet, can construct as described in the first embodiment, divide the output signal of telecommunication and the demodulation part, carry out demodulation and without the system of radiation wireless signal from optical detection part.

(the 4th embodiment)

Fig. 4 A is the figure that transmission system 4 structures of fourth embodiment of the invention are shown.In Fig. 4 A, transmission system 4 comprises transmitter installation 120, optical transmission pathway 200, receiver apparatus 320 and wireless terminal 400.Transmitter installation 120 is connected by optical transmission pathway 200 with receiver apparatus 320.Transmitter installation 120 comprises pulse train generation part 101, filter segment 121 and light modulation portion 102.Receiver apparatus 320 comprises that pulse compression part 321, optical detection part divide 301 and radiant section 312.In Fig. 4 A, have identical drawing reference numeral with the frame that has identical function among the first or the 3rd embodiment, will omit description of them.

Then, will the operation of transmission system 4 be described.Therefore the structure of this embodiment is similar to the structure (referring to Fig. 1 and 3) among the above-mentioned first and the 3rd embodiment, only describes different aspects below.

Filter segment 121 is with respect to pulse train (a) (referring to Fig. 4 B) restricted band of pulse train generation part 101 outputs, thereby the pulse duration of increase pulse train promptly increases rise time and fall time, and exports it.Fig. 4 C is the figure that the time waveform of the modulation signal (b) that transmits on the signal of telecommunication (b) of filter segment output and the optical transmission pathway 200 is shown.

The light modulating signal that pulse compression part 321 receives through optical transmission pathway 200 transmission, and compress its modulation intelligence (pulse duration), promptly reduce the rise time and/or the fall time of modulation intelligence, and export it.Fig. 4 D illustrates the figure of time waveform that pulse compression part 321 and optical detection part divide the pulse trains (c) of 301 outputs.

Therefore, according to the 4th embodiment, in the pulse duration that increases and after optical transmission, in the pulse compression part, reduce transmission signals before the optical transmission, thereby can have high broadband wireless signal of interfering steadiness with high-quality transmission, reduce the necessary bandwidth of transmitter installation and transmission channel simultaneously.

In the 4th embodiment, described from radiant section 312 radiation wireless signals and the system that wireless terminal, carries out demodulation.Yet, can construct as described in the first embodiment, divide the output signal of telecommunication and the demodulation part, carry out demodulation and without the system of radiation wireless signal from optical detection part.

(the 5th embodiment)

Fig. 5 A is the figure that transmission system 5 structures of fifth embodiment of the invention are shown.In Fig. 5 A, transmission system 5 comprises transmitter installation 130, optical transmission pathway 200, receiver apparatus 330 and wireless terminal 400.Transmitter installation 130 is connected by optical transmission pathway 200 with receiver apparatus 330.Transmitter installation 130 comprises pulse train generation part 132 and optic angle degree modulating part 131.Receiver apparatus 330 comprises beam split part 331, light delay part 332, light combination/beam split part 333, and optical detection part divides 301 and radiant section 312.Beam split part 331, light delay part 332 and light combination/beam split part 333 constitute interference of light part 334.In Fig. 5 A, have identical drawing reference numeral with the frame that has identical function among first or second embodiment, will omit description of them.

Then, will the operation of transmission system 5 be described.Therefore the structure of this embodiment is similar to the structure (referring to Fig. 1 and 2) among above-mentioned first and second embodiment, only describes different aspects below.

Pulse train generation part 132 uses the predictive encoding figure to convert input data signal D to broad pulse duration pulse train, and this pulse duration is wideer than the pulse duration of the pulse train of 101 outputs of pulse train generation part among first embodiment, and exports it.Optic angle degree modulating part 131 converts the pulse train of pulse train generation part 101 outputs to optic angle degree modulation signal, and it is sent to optical transmission pathway 200.Fig. 5 B is the figure that the time waveform of the optic angle degree modulation signal (a) that transmits on the pulse train (a) of pulse train generation part 132 output and the optical transmission pathway 200 is shown.Shown in Fig. 5 B, the pulse duration of the optic angle degree modulation signal (a) of transmission is wideer than the pulse duration among first embodiment on the pulse train (a) of pulse train generation part 132 outputs and the optical transmission pathway 200.

Beam split part 331 is cut apart the optic angle degree modulation signal through the optical transmission pathway transmission, and a light signal is input to light delay part 332, and another light signal is input to light combination/beam split part 333.Light delay part 332 is input to it light combination/beam split part 333 then for input optical signal provides predetermined propagation delay T1.Fig. 5 C is the figure of the time waveform of the light signal (b) exported of light signal that beam split part 331 output is shown (a ') and light delay part 332.Shown in Fig. 5 C, the light signal (b) of light delay part 332 output postpones T1 than light signal (a ').

Two light signals of light combination/beam split part 333 combinatorial inputs are also cut apart once more.Therefore, light combination/beam split part 333 is two light intensity modulated signals of output separately, and they are corresponding to the difference component of the modulation signal (pulse train) of optic angle degree modulation signal and have toward each other the modulation signal of polarity (being called " equation of light sub-signal " hereinafter) (c) and (d).Fig. 5 D is the figure that two equation of light sub-signals (c) and time waveform (d) are shown.Optical detection part divides 301 to convert equation of light sub-signal (c) to as the signal of telecommunication differential pulse string once more, and exports it.Shown in Fig. 5 D, it is the signals with the pulse train that reduces width that optical detection part divides the equation of light sub-signal (c) of 301 outputs.

Should be noted that the light delay amount T1 that provides in the light delay part 332 is set to less than a bit width of the pulse train of pulse train generation part 132 outputs.

Therefore, according to the 5th embodiment, can use light signal to handle and produce the one pole burst, thereby can increase the interference steadiness of wireless signal, and not increase transmitter installation and the necessary bandwidth of transmission channel by the frequency spectrum that increases pulse train.

In the 5th embodiment, light delay partly postpones the optic angle degree modulation signal that beam split is partly exported.Yet, can insert two light delay parts, make to postpone two optic angle degree modulation signals.In this case, can determine the retardation of two light delaies part, make to be input to time difference between light combination/beam split two optic angle degree modulation signals partly corresponding to light delay amount T1.

In the 5th embodiment, described from radiant section 312 radiation wireless signals and the system that wireless terminal, carries out demodulation.Yet, can construct as described in the first embodiment, divide the output signal of telecommunication and the demodulation part, carry out demodulation and without the system of radiation wireless signal from optical detection part.

(the 6th embodiment)

Fig. 6 A is the figure that transmission system 6 structures of sixth embodiment of the invention are shown.In Fig. 6 A, transmission system 6 comprises transmitter installation 130, optical transmission pathway 200, receiver apparatus 340 and wireless terminal 400.Transmitter installation 130 is connected by optical transmission pathway 200 with receiver apparatus 340.Transmitter installation 130 comprises pulse train generation part 132 and optic angle degree modulating part 131.Receiver apparatus 340 comprises interference of light part 346, photo-equilibrium test section 347 and radiant section 312.Interference of light part 346 has beam split part 331, light delay part 332, light combination/beam split part 333.Photo-equilibrium test section 347 has that first optical detection part divides that 341, second optical detection part divides 342, decay part 343 and built-up section 345.In Fig. 6 A, have identical drawing reference numeral with the frame that has identical function among the 5th embodiment, will omit description of them.

Then, will the operation of transmission system 6 be described.The structure of this embodiment is similar to the structure (referring to Fig. 5) among above-mentioned the 5th embodiment, therefore will simplify the description to same section.Pulse train generation part 132 uses the predictive encoding figures to convert input data signal D to broad pulse duration pulse train (a), and export it (referring to Fig. 6 B).Optic angle degree modulating part 131 converts the pulse train of pulse train generation part 101 outputs to optic angle degree modulation signal, and it is sent to optical transmission pathway 200.

Beam split part 331 is cut apart the optic angle degree modulation signal through optical transmission pathway transmission, and light signal (a ') (referring to Fig. 6 C) is input to light delay part 332, and another light signal is input to light combination/beam split part 333.Light delay part 332 is input to light combination/beam split part 333 with light signal (b) (referring to Fig. 6 C), and this light signal (b) obtains by predetermined propagation delay T1 is provided for input optical signal.

Light combination/beam split part 333 is divided into two equation of light sub-signals with two input optical signals.First optical detection part divides 341 with first a differential pulse string (c) that converts to once more as the signal of telecommunication in the equation of light sub-signal of light combination/beam split part 333 outputs, and exports it.Second optical detection part divides 342 another equation of light sub-signals with light combination/beam split part 333 output to convert the second differential pulse string (d) as the signal of telecommunication once more to, and exports it.Fig. 6 D is the figure that the time waveform of the first differential pulse string (c) and the second differential pulse string (d) is shown.

Decay part 343 is that second optical detection part divides the second differential pulse string (d) of 342 outputs that predetermined propagation delay T2 is provided, and exports second pulse train (e).Built-up section 345 will divide 341 the first differential pulse string (c) and the second differential pulse string (e) combination with predetermined propagation delay T2 from decay part 343 from first optical detection part, to produce and to export bipolar differential pulse string (f).Fig. 6 E is the figure that the time waveform of the first differential pulse string (c) that is input to built-up section 345 and the second differential pulse string (e) is shown.Fig. 6 F is the figure of time waveform that the bipolar differential pulse string (f) of built-up section 345 output is shown.

The light delay amount T1 that provides in the light delay part 332 is configured to the bit width less than pulse train.The electric delay amount T2 that provides in the decay part 343 preferably equals light delay amount T1.

Therefore, according to the 6th embodiment, can use light signal to handle and produce bipolar burst, thereby can increase the interference steadiness of wireless signal, and not increase transmitter installation and the necessary bandwidth of transmission channel by the frequency spectrum that increases pulse train.

In the 6th embodiment, light delay partly postpones the optic angle degree modulation signal that beam split is partly exported.Yet, can insert two light delay parts, make to postpone two optic angle degree modulation signals.In this case, can determine the retardation of two light delaies part, make to be input to time difference between light combination/beam split two optic angle degree modulation signals partly corresponding to light delay amount T1.

In the 6th embodiment, only postpone second differential pulse that second optical detection part divides output.Yet, can insert two light delay parts, make to postpone first and second differential pulses.In this case, can determine the retardation of two light delaies part, make time difference between first and second differential pulses that are input to built-up section corresponding to light delay amount T2.

In the 6th embodiment, described from radiant section 312 radiation wireless signals and the system that wireless terminal, carries out demodulation.Yet, can construct as described in the first embodiment, divide the output signal of telecommunication and the demodulation part, carry out demodulation and without the system of radiation wireless signal from optical detection part.

(the 7th embodiment)

Fig. 7 is the figure that transmission system 7 structures of seventh embodiment of the invention are shown.In Fig. 7, transmission system 7 comprises transmitter installation 140, optical transmission pathway 200 and receiver apparatus 350.Transmitter installation 140 is connected by optical transmission pathway 200 with receiver apparatus 350.Transmitter installation 140 comprises the first pulse train generation part 141, the second pulse train generation part 142, first light modulation portion 143, second light modulation portion 144 and light built-up section 145.Receiver apparatus 350 comprises that optical detection part divides 301 and demodulation/separating part 351.

Then, will the operation of transmission system 7 be described.The first pulse train generation part 141 converts first pulse train to according to being scheduled to will to import the first data-signal D1 corresponding to first coded graphics of data-signal, and exports it.The second pulse train generation part 142 will be imported the second data-signal D1 according to second coded graphics that is different from predetermined first coded graphics corresponding to data-signal and convert second pulse train to, and export it.Provide first and second light modulation portion 143 and 144 corresponding to first and second pulse trains, pulse train is converted to light modulating signal respectively and exports them.Light built-up section 145 makes up the light modulating signals of first and second light modulation portion 143 and 144 outputs, and it is sent to optical transmission pathway 200.Optical detection part divides 301 to have square detection characteristic, and it converts the light modulating signal of optical transmission pathway 200 transmission once more to the signal of telecommunication and export it.Demodulation/separating part 351 divides 301 signals of telecommunication of exporting with the acquisition pulse train according to unique decoding figure selecting ground demodulation optical detection part corresponding to first and/or second coded graphics, and extracts the first data-signal D1 and/or the second data-signal D2 and export it.

The modulation type of the pulse train that uses in the first and second pulse train generation parts 141 and 142 is the pulse position modulation type, wherein converts data-signal to pulse position information according to predetermined coded graphics corresponding to data-signal.The first and second pulse train generation parts 141 and 142 further reduce the pulse duration of pulse train, with spread spectrum to the frequency band of broad, power peak that therefore can the suppressor pulse string.Therefore, can reduce at the interference level that may influence other pulse train with the combination of other pulse train or when multiplexed.In addition,, can improve the interference steadiness by specifying specific coding/decoding figure corresponding to each data-signal, thus can multiplexed asynchronously a plurality of pulse trains.

When multiplexed at least three data-signals, following structure is possible.Provide a plurality of pulse trains that part and light modulation portion take place, coded graphicss different between the data-signal and decoding figure are distributed to each data-signal, pulse train takes place to produce in the part at pulse train, in light modulation portion, convert light modulating signal to, combination and carry out optical transmission in the light built-up section.In this case, be similar to the situation of two data-signals, demodulation/separating part uses decoding figure selecting ground demodulation optical detection part to divide the signal of telecommunication of output, and extracts each data-signal and export it.

Therefore,, convert a plurality of data-signals to pulse train, convert pulse train to light modulating signal, make up and carry out optical transmission according to the coded graphics corresponding to a plurality of data-signals that differ from one another, predetermined according to the 7th embodiment.Afterwards, will convert the signal of telecommunication to, and use unique decoding figure selecting ground demodulation desired data signal, and extract corresponding to the used coded graphics of transmitter installation through the light signal of optical transmission.Therefore, can prevent owing to interfere the quality deterioration cause between the data-signal that simply mode is multiplexed in high quality and hold a plurality of data-signals, and does not need the synchronizing process between a plurality of data-signals.

Should be noted that optical detection part divides the signal of telecommunication of 301 outputs can utilize radiant section as radio-wave radiation.In this case, the wireless terminal that receives radio wave uses demodulation/separated part to assign to extract the desired data signal.

(the 8th embodiment)

Fig. 8 is the figure that transmission system 8 structures of eighth embodiment of the invention are shown.In Fig. 8, transmission system 8 comprises transmitter installation 140, optical transmission pathway 200 and receiver apparatus 360.Transmitter installation 140 is connected by optical transmission pathway 200 with receiver apparatus 360.Transmitter installation 140 comprises the first pulse train generation part 141, the second pulse train generation part 142, first light modulation portion 143, second light modulation portion 144 and light built-up section 145.Receiver apparatus 360 comprises that beam split part 361, first optical detection part divide that 362, second optical detection part divides 363, first demodulation/separating part 364 and second demodulation/separating part 365.In Fig. 8, have identical drawing reference numeral with the frame that has identical function among the 7th embodiment, will omit description of them.

Then, will the operation of transmission system 8 be described.The structure of this embodiment is similar to the structure (referring to Fig. 7) among above-mentioned the 7th embodiment, therefore followingly will only describe different piece.Beam split part 361 is divided into the light modulating signal of optical transmission pathway 200 transmission a plurality of signals (among Fig. 8 being 2) and exports them.The light modulating signal of cutting apart corresponding to beam split part 361 provides first and second optical detection parts to divide 362 and 363, and they convert each light modulating signal once more to the signal of telecommunication and export them.Divide the signal of telecommunication of 362 and 363 outputs that first and second demodulation/separating part 364 and 365 is provided corresponding to first and second optical detection parts, they are according to unique decoding figure selecting ground demodulation signal of telecommunication corresponding to first and second coded graphicss, extract the first data-signal D1 and the second data-signal D2 respectively, and export them.

When multiplexed at least three data-signals, following structure is possible.Provide a plurality of pulse trains that part and light modulation portion take place, coded graphicss different between the data-signal and decoding figure are distributed to each data-signal, pulse train takes place to produce in the part at pulse train, in light modulation portion, convert light modulating signal to, combination and carry out optical transmission in the light built-up section.In this case, beam split part will import light modulating signal and be divided into a plurality of signals, detect the light modulating signal through cutting apart in each optical detection part divides, with utilizing the decoding figure selecting demodulation they, to extract each data-signal.

Therefore,, convert a plurality of data-signals to pulse train, convert light modulating signal to, make up then and carry out optical transmission according to the 8th embodiment.Afterwards,, carry out the light multichannel and decompose, convert each light signal to the signal of telecommunication, and separate to be in harmonious proportion and extract each data-signal at receiver side.Therefore, can prevent that simply mode realizes the multiplexed transmission of a plurality of data-signals in high quality, and does not need the synchronizing process between a plurality of data-signals owing to interfere the quality deterioration that causes between the data-signal.

Should be noted that each optical detection part divides the signal of telecommunication of output can utilize radiant section as radio-wave radiation.In this case, the wireless terminal that receives radio wave uses demodulation/separated part to assign to extract the desired data signal.

(the 9th embodiment)

Fig. 9 is the figure that transmission system 9 structures of ninth embodiment of the invention are shown.In Fig. 9, transmission system 9 comprises transmitter installation 150, optical transmission pathway 200 and receiver apparatus 370.Transmitter installation 150 is connected by optical transmission pathway 200 with receiver apparatus 370.Transmitter installation 150 comprises the first pulse train generation part 141, the second pulse train generation part 142, first light modulation portion 143, second light modulation portion 144, light built-up section 145 and data light modulating part 151.Receiver apparatus 370 comprises that optical detection part divides 301, data separating part 371 and demodulation/separating part 351.In Fig. 9, have identical drawing reference numeral with the frame that has identical function among the 7th embodiment, will omit description of them.Structure shown in Figure 9 is different from structure shown in Figure 7, has wherein increased data light modulating part 151 and data separating part 371.

Then, will the operation of transmission system 9 be described.The structure of this embodiment is similar to the structure (referring to Fig. 7) among above-mentioned the 7th embodiment, therefore followingly will only describe different piece.Clock rate is lower than the 3rd data-signal D3 input data light modulating part 151 of first and second pulse trains.The 3rd data-signal D3 that data light modulating part 151 will be imported converts light modulating signal to and exports it.Light built-up section 145 makes up the light modulating signal of first and second light modulation portion 143 and 144 outputs and the light modulating signal of data light modulating part 151 outputs, and the result is sent to optical transmission pathway 200.Data separating part 371 is isolated the 3rd data-signal D3 and is exported it from optical detection part divides the signals of telecommunication of 301 outputs, and other signal is outputed to demodulation/separating part 351.

When multiplexed at least three data-signals, following structure is possible.Provide light modulation portion corresponding to each pulse train, composite wave in the light built-up section carries out optical transmission then.At receiver side, use at least three pulse trains of decoding figure selecting ground demodulation.

Therefore, according to the 9th embodiment, convert a plurality of data-signals to pulse train, multiplexed and carry out optical transmission, the data-signal that has the repetition period that is lower than pulse train simultaneously is by multiplexed, thereby can realize the multiplexed transmission of a plurality of data-signals in simple mode.

Should be noted that each optical detection part divides the signal of telecommunication of output can utilize radiant section as radio-wave radiation.In this case, the wireless terminal that receives radio wave uses demodulation/separated part to assign to extract the desired data signal.

(the tenth embodiment)

Figure 10 is the figure that transmission system 10 structures of tenth embodiment of the invention are shown.In Figure 10, transmission system 10 comprises transmitter installation 160, optical transmission pathway 200 and receiver apparatus 350.Transmitter installation 160 is connected by optical transmission pathway 200 with receiver apparatus 350.Transmitter installation 160 comprises the first pulse train generation part 141, the second pulse train generation part 142, composite part 161 and light modulation portion 162.Receiver apparatus 350 comprises that optical detection part divides 301 and demodulation/separating part 351.In Figure 10, have identical drawing reference numeral with the frame that has identical function among the 7th embodiment, will omit description of them.Structure shown in Figure 10 is different from structure shown in Figure 7, has wherein substituted light built-up section 145 with composite part 161 and light modulation portion 162.

Then, will the operation of transmission system 10 be described.The structure of this embodiment is similar to the structure (referring to Fig. 7) among above-mentioned the 7th embodiment, therefore followingly will only describe different piece.The pulse train of composite part 161 synthetic first and second pulse train generation parts 141 and 142 outputs is also exported the result.Light modulation portion 162 converts the composite signal of composite part 161 outputs to light modulating signal, and it is sent to optical transmission pathway 200.

When multiplexed at least three data-signals, following structure is possible.The synthetic pulse train that obtains for each data-signal in composite part, and in light modulation portion, modulate.At receiver side, use the signal of telecommunication of decoding figure selecting ground light modulated test section output, to extract each data-signal.

Therefore, according to the tenth embodiment, convert a plurality of data-signals to pulse train according to coded graphics corresponding to a plurality of data-signals that differ from one another and predetermined, the composite pulse string also converts them to light modulating signal, carries out optical transmission then.Afterwards, convert the light signal of optical transmission to the signal of telecommunication,, extract thus according to unique decoding figure selecting ground demodulation desired data signal corresponding to coded graphics used in the transmitter installation.Therefore, can prevent owing to interfere the quality deterioration cause between the data-signal, and can be in simple mode multiplexed in high quality and hold a plurality of data-signals, and do not need the synchronizing process between a plurality of data-signals.

(the 11 embodiment)

Figure 11 is the figure that transmission system 11 structures of eleventh embodiment of the invention are shown.In Figure 11, transmission system 11 comprises transmitter installation 160, optical transmission pathway 200 and receiver apparatus 360.Transmitter installation 160 is connected by optical transmission pathway 200 with receiver apparatus 360.Transmitter installation 160 comprises the first pulse train generation part 141, the second pulse train generation part 142, composite part 161 and light modulation portion 162.Receiver apparatus 360 comprises that beam split part 361, first optical detection part divide that 362, second optical detection part divides 363, first demodulation/separating part 364 and second demodulation/separating part 365.In Figure 11, have identical drawing reference numeral with the frame that has identical function among the 8th or the tenth embodiment, will omit description of them.

Then, will the operation of transmission system 11 be described.The structure of this embodiment is similar to the structure (referring to Figure 10) among above-mentioned the tenth embodiment, therefore followingly will only describe different aspects.Beam split part 361 is divided into the light modulating signal of optical transmission pathway 200 transmission a plurality of signals (among Figure 11 being 2) and exports them.The light modulating signal of cutting apart corresponding to beam split part 361 provides first and second optical detection parts to divide 362 and 363, and they convert each light modulating signal the signal of telecommunication to and export them.Divide the signal of telecommunication of 362 and 363 outputs that first and second demodulation/separating part 364 and 365 is provided corresponding to first and second optical detection parts, they are according to unique decoding figure selecting ground demodulation signal of telecommunication corresponding to first and second coded graphicss, extract the first data-signal D1 and the second data-signal D2 respectively, and export them.

That describes among the structure of multiplexed at least three data-signals and the 8th and the tenth embodiment is identical.

Therefore,, convert a plurality of data-signals to pulse train, synthesize them and convert light modulating signal to, carry out optical transmission then according to the 11 embodiment.Afterwards,, carry out the light multichannel and decompose, convert each light signal to the signal of telecommunication, and separate to be in harmonious proportion and extract each data-signal at receiver side.Therefore, can prevent that simply mode realizes the multiplexed transmission of a plurality of data-signals in high quality, and does not need the synchronizing process between a plurality of data-signals owing to interfere the quality deterioration that causes between the data-signal.

Should be noted that each optical detection part divides the signal of telecommunication of output can utilize radiant section as radio-wave radiation.In this case, the wireless terminal that receives radio wave uses demodulation/separated part to assign to extract the desired data signal.

(the 12 embodiment)

Figure 12 is the figure that transmission system 12 structures of twelveth embodiment of the invention are shown.In Figure 12, transmission system 12 comprises transmitter installation 170, optical transmission pathway 200 and receiver apparatus 380.Transmitter installation 170 is connected by optical transmission pathway 200 with receiver apparatus 380.Transmitter installation 170 comprises the first pulse train generation part 141, the second pulse train generation part 142, composite part 171 and light modulation portion 162.Receiver apparatus 380 comprises that beam split part 381, first optical detection part divide that 362, second optical detection part divides 363, first demodulation/separating part 364, second demodulation/separating part 365 and data light test section 382.In Figure 12, have identical drawing reference numeral with the frame that has identical function among the 11 embodiment, will omit description of them.Structure shown in Figure 12 is different from structure shown in Figure 11, and wherein composite part 171 synthesizes the 3rd data-signal D3, and beam split part 381 is divided into three with signal one, and data light test section 382 is newly-increased.

Then, will the operation of transmission system 12 be described.The structure of this embodiment is similar to the structure (referring to Figure 11) among above-mentioned the 11 embodiment, therefore followingly will only describe different aspects.Synthetic first and second pulse trains of composite part 171 and the 3rd data-signal D3 also are lower than first and second pulse trains with the clock rate that the result outputs to light modulation portion 162, the three data-signal D3.Beam split part 381 is divided into three signals with the light modulating signal of optical transmission pathway 200 transmission.Data light test section 382 beam split part 381 is cut apart and the light modulating signal exported in one convert the signal of telecommunication once more to, and separate and export the 3rd data-signal D3.

When multiplexed at least three data-signals, following structure is possible.Synthetic each pulse train in composite part is divided into the number corresponding to data-signal number in the beam split part, converts the signal of telecommunication in optical detection part divides, and uses coded graphics to its optionally demodulation in demodulation/separating part.

Therefore, according to the 12 embodiment, convert a plurality of data-signals to pulse train and multiplexed, the data-signal that has the repetition period that is lower than pulse train simultaneously is by multiplexed and carry out optical transmission, thereby can realize the multiplexed transmission of a plurality of data-signals in simple mode.

Should be noted that each optical detection part divides the signal of telecommunication of output can utilize radiant section as radio-wave radiation.In this case, the wireless terminal that receives radio wave uses demodulation/separated part to assign to extract the desired data signal.

(the 13 embodiment)

Figure 13 is the figure that transmission system 13 structures of thriteenth embodiment of the invention are shown.In Figure 13, transmission system 13 comprises transmitter installation 180, optical transmission pathway 200 and receiver apparatus 350.Transmitter installation 180 is connected by optical transmission pathway 200 with receiver apparatus 350.Transmitter installation 180 comprises the first pulse train generation part 141, the second pulse train generation part 142, first light modulation portion 143, second light modulation portion 144, light built-up section 145 and wavelength control part 181.Receiver apparatus 350 comprises that optical detection part divides 301 and demodulation/separating part 351.In Figure 13, have identical drawing reference numeral with the frame that has identical function among the 7th embodiment, will omit description of them.Structure shown in Figure 13 is different from structure shown in Figure 7, has wherein increased wavelength control part 181 newly.

Then, will the operation of transmission system 13 be described.The structure of this embodiment is similar to the structure (referring to Fig. 7) among above-mentioned the 7th embodiment, therefore followingly will only describe different aspects.Wavelength control part 181 is controlled stablizing the wavelength of light modulating signals of first and second light modulation portion 143 and 144 outputs, and regulates and make wavelength differ from one another.

When multiplexed at least three data-signals, can construct the wavelength control part to control the wavelength of each light modulation portion.

Therefore, according to the 13 embodiment, in this structure, convert a plurality of data-signals to pulse train and convert light modulating signal again to, and make up and optical transmission, optionally demodulation and extract the desired data signal from the signal that receives then, the wavelength of suitably controlling light modulating signal make and can prevent owing to interfere the quality deterioration that causes between the light modulating signal, and multiplexed and hold a plurality of data-signals with high-quality.

(the 14 embodiment)

Figure 14 is the figure that transmission system 14 structures of fourteenth embodiment of the invention are shown.In Figure 14, transmission system 14 comprises transmitter installation 160, optical transmission pathway 200, receiver apparatus 600, first wireless terminal 401 and second wireless terminal 402.Transmitter installation 160 is connected by optical transmission pathway 200 with receiver apparatus 600.Transmitter installation 160 comprises the first pulse train generation part 141, the second pulse train generation part 142, composite part 161 and light modulation portion 162.Receiver apparatus 600 comprises that optical detection part divides 301 and radiant section 601.In Figure 14, have identical drawing reference numeral with the frame that has identical function among the tenth embodiment, will omit description of them.Structure shown in Figure 14 is different from structure shown in Figure 10, wherein substitutes demodulation/separating part 351 with radiant section 601.

Then, will the operation of transmission system 14 be described.The structure of this embodiment is similar to the structure (referring to Figure 10) among above-mentioned the tenth embodiment, therefore followingly will only describe different aspects.Radiant section 601 amplifies and/or divides the composite signal of 301 outputs to carry out waveform shaping to optical detection part, then it is radiated as wireless signal in the air.Provide first and second wireless terminals 401 and 402 corresponding to the first and second pulse train generation parts 141 and 142, they are according to the wireless signal of unique decoding figure demodulation radiant section 601 radiation corresponding to coded graphics, to extract the first data-signal D1 and the second data-signal D2 respectively.

Therefore, according to the 14 embodiment, convert data-signal to pulse train according to unique predetermined coded graphics, and carry out optical transmission, then as the wireless signal radiation corresponding to data-signal.In wireless terminal according to the signal of unique decoding figure demodulation corresponding to coded graphics corresponding to the signal that receives.Therefore, can high-quality transmission have high broadband wireless signal of interfering steadiness, the raising capacity, and multiplexed and hold a plurality of wireless signals (wireless terminal).

(the 15 embodiment)

Figure 15 A is the figure that transmission system 15 structures of fifteenth embodiment of the invention are shown.In Figure 15 A, transmission system 15 comprises transmitter installation 500, optical transmission pathway 200, receiver apparatus 320, first wireless terminal 401 and second wireless terminal 402.Transmitter installation 500 is connected by optical transmission pathway 200 with receiver apparatus 320.Transmitter installation 500 comprises the first pulse train generation part 501, the second pulse train generation part 502, composite part 161 and light modulation portion 162.Receiver apparatus 320 comprises that pulse compression part 321, optical detection part divide 301 and radiant section 312.In Figure 15 A, have identical drawing reference numeral with the frame that has identical function among the 3rd or the 14 embodiment, will omit description of them.

Then, will the operation of transmission system 15 be described.Data-signal D1 is input to the first pulse train generation part 501.Data-signal D2 is input to the second pulse train generation part 502.The first and second pulse train generation parts 501 and 502 use the predictive encoding figure to convert data-signal D1 and D2 to pulse train (a), and wherein each pulse is a trapezoidal pulse, and output pulse string (referring to Figure 15 B).The coded graphics that uses in the first and second pulse train generation parts 501 and 502 differs from one another.The pulse train of composite part 161 synthetic first and second pulse train generation parts 501 and 502 outputs is also exported the result.Light modulation portion 162 converts the composite signal of composite part 161 outputs light modulating signal (a) to and it is sent to optical transmission pathway 200.Pulse compression part 321 receives the light modulating signal (a) of optical transmission pathway 200 transmission and compresses its modulation intelligence (pulse train or composite signal), promptly reduces the rise time and/or the fall time of modulation intelligence and exports result (referring to Figure 15 C).

Therefore, according to the 15 embodiment, handle the pulse duration that reduces transmission signals by using optical transmission light signal afterwards.Therefore, can increase frequency spectrum, and not increase transmitter installation and the necessary bandwidth of transmission channel, and can further increase the interference steadiness of wireless signal, and multiplexed and hold a plurality of wireless terminals.

Can partly come to substitute the pulse compression part with wavelength dispersion with wavelength dispersion characteristics, pulse compression part receiving light power degree modulation signal, compression is as the pulse duration of the pulse train or the composite signal of modulation intelligence, or reduces rise time and/or fall time and export it.In this case, preferably, light modulation portion is used the direct sunshine modulating system, wherein injects semi-conductive electric current with the modulation of input pulse string, and the output light intensity modulation signal.Therefore, can utilize the non-linear pulse duration that reduces light signal of optical fiber, thereby can realize transmitting and do not use the optical transmission system of particular device with high-quality and low-cost mode.

Should be noted that in the 15 embodiment optical detection part divides the signal of telecommunication that detects as the wireless signal radiation.Yet in the tenth embodiment, this structure makes receiver apparatus use demodulation/separating part optionally to extract each data-signal.

(the 16 embodiment)

Figure 16 A is the figure that transmission system 16 structures of sixteenth embodiment of the invention are shown.In Figure 16 A, transmission system 16 comprises transmitter installation 510, optical transmission pathway 200, receiver apparatus 320, first wireless terminal 401 and second wireless terminal 402.Transmitter installation 510 is connected by optical transmission pathway 200 with receiver apparatus 320.Transmitter installation 510 comprises the first pulse train generation part 141, the second pulse train generation part 142, filter segment 511 and 512, composite part 161 and light modulation portion 162.Receiver apparatus 320 comprises that pulse compression part 321, optical detection part divide 301 and radiant section 312.In Figure 16 A, have identical drawing reference numeral with the frame that has identical function among the 4th or the 14 embodiment, will omit description of them.

Then, will the operation of transmission system 16 be described.The structure of this embodiment is similar to the structure (referring to Figure 14 and 15) among the above-mentioned the 14 and 15 embodiment, therefore followingly will only describe different aspects.The first and second pulse train generation parts 141 and 142 and composite part 161 between insert filter segment 511 and 512 respectively, to limit the frequency band (referring to Figure 16 B) that the pulse train (a) of part output takes place each pulse train, to increase pulse duration, promptly increase rise time/fall time and output (referring to Figure 16 C).Pulse compression part 321 receives the light modulating signal of optical transmission pathway 200 transmission and compresses its modulation intelligence (pulse duration), promptly reduces rise time and/or the fall time and the output (referring to Figure 16 D) of modulation intelligence.

Therefore, according to the 16 embodiment, after optical transmission, reduce the pulse duration of transmission signals increasing before the optical transmission.Therefore, can high-quality transmission have high broadband wireless signal of interfering steadiness, and not increase transmitter installation and the necessary bandwidth of transmission channel, and multiplexed and hold a plurality of wireless terminals.

Filter segment can be inserted between composite part 161 and the light modulation portion 162.

Should be noted that in the 16 embodiment optical detection part divides the signal of telecommunication that detects as the wireless signal radiation.Yet in the tenth embodiment, this structure makes receiver apparatus use demodulation/separating part optionally to extract each data-signal.

(the 17 embodiment)

Figure 17 A is the figure that transmission system 17 structures of seventeenth embodiment of the invention are shown.In Figure 17 A, transmission system 17 comprises transmitter installation 520, optical transmission pathway 200, receiver apparatus 330, first wireless terminal 401 and second wireless terminal 402.Transmitter installation 520 is connected by optical transmission pathway 200 with receiver apparatus 330.Transmitter installation 520 comprises the first pulse train generation part 521, the second pulse train generation part 522, composite part 161 and optic angle degree modulating part 131.Receiver apparatus 330 comprises beam split part 331, light delay part 332, light combination/beam split part 333, and optical detection part divides 301 and radiant section 312.In Figure 17 A, have identical drawing reference numeral with the frame that has identical function among the 5th or the 14 embodiment, will omit description of them.

Then, will the operation of transmission system 17 be described.The structure of this embodiment is similar to the structure (referring to Fig. 5) among above-mentioned the 5th embodiment, therefore followingly will only describe different aspects.The first and second pulse train generation parts 521 and 522 convert input data signal D1 and D2 to first and second pulse trains according to the predictive encoding figure corresponding to data-signal, and export them.The pulse duration of the pulse train (a) of the first and second pulse train generation parts 521 and 522 outputs is wider than the first and second pulse train generation parts 141 and 142 pulse trains of exporting (referring to Figure 17 B) among the 7th embodiment.Composite part 161 synthesizes the pulse trains of the first and second pulse train generation parts 521 and 522 outputs and the result is outputed to optic angle degree modulating part 131.Afterwards, identical operations among execution and the 5th embodiment makes from radiant section 312 radiation one pole bursts (referring to Figure 17 C and 17D).

Therefore, according to the 17 embodiment, can utilize light signal to handle and produce the one pole burst.Therefore, can increase the frequency spectrum of pulse train, and not increase the burden of transmitter installation and transmission channel, and can further improve the interference steadiness of wireless signal, and multiplexed and hold a plurality of wireless terminals.

In the 17 embodiment, light delay partly postpones in the optic angle degree modulation signal that beam split partly exports.Yet can insert two light delay parts, to postpone two optic angle degree modulation signals.In this case, can determine the retardation of two light delaies part, make to be input to time difference between light combination/beam split two optic angle degree modulation signals partly corresponding to light delay amount T1.

Should be noted that in the 17 embodiment optical detection part divides the signal of telecommunication that detects as the wireless signal radiation.Yet in the tenth embodiment, this structure makes receiver apparatus use demodulation/separating part optionally to extract each data-signal.

(the 18 embodiment)

Figure 18 A is the figure that transmission system 18 structures of eighteenth embodiment of the invention are shown.In Figure 18 A, transmission system 18 comprises transmitter installation 520, optical transmission pathway 200, receiver apparatus 340, first wireless terminal 401 and second wireless terminal 402.Transmitter installation 520 is connected by optical transmission pathway 200 with receiver apparatus 340.Transmitter installation 520 comprises the first pulse train generation part 521, the second pulse train generation part 522, composite part 161 and optic angle degree modulating part 131.Receiver apparatus 340 comprises interference of light part 346, photo-equilibrium test section 347 and radiant section 312.Interference of light part 346 has beam split part 331, light delay part 332, light combination/beam split part 333.Photo-equilibrium test section 347 comprises that first optical detection part divides that 341, second optical detection part divides 342, decay part 343 and built-up section 345.In Figure 18 A, have identical drawing reference numeral with the frame that has identical function among the 6th or the 17 embodiment, will omit description of them.

Then, will the operation of transmission system 18 be described.The structure of this embodiment is similar to the structure (referring to Fig. 6) among above-mentioned the 6th embodiment, therefore followingly will only describe different aspects.The first and second pulse train generation parts 521 and 522 convert input data signal D1 and D2 to first and second pulse trains according to the predictive encoding figure corresponding to data-signal, and export them.The pulse duration of the pulse train (a) of the first and second pulse train generation parts 521 and 522 outputs is wider than the first and second pulse train generation parts 141 and 142 pulse trains of exporting (referring to Figure 18 B) among the 7th embodiment.Composite part 161 synthesizes the pulse trains of the first and second pulse train generation parts 521 and 522 outputs and the result is outputed to optic angle degree modulating part 131.Afterwards, identical operations among execution and the 6th embodiment makes from the bipolar burst of radiant section 312 radiation (referring to Figure 18 C to 18F).

Therefore, according to the 18 embodiment, can utilize light signal to handle and produce bipolar burst.Therefore, can increase the frequency spectrum of pulse train, and not increase the burden of transmitter installation and transmission channel, and can further improve the interference steadiness of wireless signal, and multiplexed and hold a plurality of wireless terminals.

In the 18 embodiment, light delay partly postpones in the optic angle degree modulation signal that beam split partly exports.Yet can insert two light delay parts, to postpone two optic angle degree modulation signals.In this case, can determine the retardation of two light delaies part, make to be input to time difference between light combination/beam split two optic angle degree modulation signals partly corresponding to light delay amount T1.

In the 18 embodiment, only postpone second differential pulse that second optical detection part divides output.Yet, can insert two light delay parts, make to postpone first and second differential pulses simultaneously.In this case, can determine the retardation of two light delaies part, make time difference between first and second differential pulses that are input to built-up section corresponding to retardation T2.

Should be noted that in the 18 embodiment optical detection part divides the signal of telecommunication that detects as the wireless signal radiation.Yet in the tenth embodiment, this structure makes receiver apparatus use demodulation/separating part optionally to extract each data-signal.

In the 3rd, the 4th, the 5th, the 6th embodiment, the pulse compression part is provided in receiver apparatus, but can be provided in the optical transmission pathway.

In the first to the 18 embodiment, the number of pulse train radiant section and wireless terminal all is 2, but their number and nonessential identical.Also can use the number beyond 2.

Industrial applicibility

Optical transmission system of the present invention and use therein transmitter installation and receiver apparatus can transmit weak point Pulse signal, and be not subjected to the impact of the characteristic of transmission channel, be useful in fields such as communications therefore.

Claims (1)

1. optical transmission system that is used for a data-signal of optical transmission, it comprises:

Pulse train generation part is used for converting data-signal to a pulse train according to a unique predetermined coded graphics corresponding to data-signal, and output pulse string;

Optic angle degree modulating part is used for converting the pulse train that pulse train takes place partly to export to optic angle degree modulation signal, and exports this signal,

Optical transmission pathway is used to transmit the optic angle degree modulation signal that optic angle degree modulating part is exported;

Interference of light part is used to receive the optic angle degree modulation signal that transmits on the optical transmission pathway and detects relevant as between the phase ortho position of the pulse train of modulation intelligence, has polarity toward each other and corresponding to two equation of light sub-signals of the difference component of pulse train with output,

The first optical detection part branch is used for first a differential pulse string that converts to once more as the signal of telecommunication of two equation of light sub-signals that the interference of light is partly exported, and exports the first differential pulse string;

The second optical detection part branch, another that is used for two equation of light sub-signals that the interference of light is partly exported converts the second differential pulse string as the signal of telecommunication once more to, and exports the second differential pulse string;

Decay part is used to first optical detection part to divide the first differential pulse string of output and/or second optical detection part to divide the second differential pulse string of output that predetermined electric delay amount is provided, and exports the first differential pulse string and/or the second differential pulse string;

Built-up section is used for the first differential pulse string and the combination of the second differential pulse string with decay part output, to export bipolar differential pulse string; With

The data signal extraction device is used for according to unique decoding figure corresponding to coded graphics, obtains to take place from pulse train the pulse train of part output from the bipolar differential pulse string of built-up section output, and extract data-signal from pulse train.

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