JP4238850B2 - Elevator signal transmission device - Google Patents

Description

  The present invention relates to an information communication apparatus for transmitting and receiving light or radio waves including a signal to transmit multimedia information such as images, sounds, or characters, and more particularly to information communication means for transmitting radio waves in the millimeter wave band in an elevator shaft. The present invention relates to an elevator signal transmission device used in the above.

  The signal transmission system between the elevator car and the machine room is connected to the machine room by a cable (hereinafter referred to as a tail cable) attached to the lower part of the elevator car and is a data signal such as a video signal, an audio signal, or control data. Is transmitting. The tail cable includes a power line. When it becomes a 200m high-rise elevator, the weight of the tail cable is comparable to the weight of 3 to 5 people of the elevator, and in addition, it is an expensive cable that requires durability of flexibility. Become. In addition, the weight of the rider and the elevator car is significant. Accordingly, in order to increase the speed of the high-rise elevator, how to reduce the weight associated with the elevator car is a development issue.

  Structural weight reduction is generally used as a method for reducing the weight of an elevator car, and attempts have been made to make it wireless in order to make a tail cable with a small diameter. As shown in FIG. 7, the elevator car and the machine room are wirelessly connected by a tightly coupled wireless system using a balanced cable and a loop antenna, and video signals and audio signals are transmitted to reduce the weight of the tail cable (for example, Patent Document 1).

JP-A-6-227766 (first page, FIG. 1)

  As described above, the conventional elevator signal transmission apparatus is a tightly coupled wireless system in which the signal transmission distance is always constant at a short distance, and is a coarsely coupled wireless system capable of transmitting and receiving even if the signal transmission distance varies. It cannot be realized. In addition, in order to cope with future multimedia, there was no particular consideration for transmitting a large amount of data at high speed.

  The present invention has been made in order to solve the above-described problems, and an object of the present invention is to obtain an elevator signal transmission apparatus based on a coarse coupling wireless system that can transmit and receive even if the transmission distance of a signal varies. It is another object of the present invention to provide an elevator signal transmission device capable of transmitting a large amount of data at high speed in order to cope with future multimedia.

  An elevator signal transmission device according to the present invention is an elevator signal transmission device that wirelessly transmits signals using signal transmission devices provided in an elevator car and a machine room, respectively, and has millimeter waves with different transmission frequencies and reception frequencies. At least one or more signals are bidirectionally transmitted using a carrier wave.

  In addition, the signal transmission device is installed in the upper and lower parts of the car, and at least one signal transmission system is installed in each of the uppermost part and the lowermost part of the elevator shaft, thereby duplicating the signal transmission system.

  In addition, the signal transmission device combines a digital data signal, a video signal, and an audio signal into a microwave, and converts the microwave received from the microwave transmitter into a millimeter wave and receives the microwave. A millimeter wave transmitter / receiver that converts the converted millimeter wave into microwave again, and a microwave receiver that demodulates the microwave received from the millimeter wave transmitter / receiver again into a digital data signal, video signal, and audio signal, respectively. is there.

  The microwave receiver follows the fluctuation in the frequency of the microwave from the millimeter wave transceiver.

  Also, the digital data signal is converted into a VHF frequency and synthesized with a video signal and an audio signal.

  The video signal and the audio signal are NTSC signals, which are synthesized with the digital data signal after being converted to the frequency of the VHF TV channel.

  In addition, in the VHF TV channel, the transmission channel and the reception channel are the same.

  In addition, the VHF TV channel has a transmission channel and a reception channel different from each other by one or more channels.

  In addition, the apparatus includes a calculation unit that measures the received power of the microwave received by the microwave receiving unit and calculates the lift distance of the cage from the received power.

  Further, the apparatus includes a calculation unit that measures the Doppler frequency of the reception frequency of the microwave received by the microwave reception unit and calculates the raising / lowering speed and the raising / lowering distance of the cage from the Doppler frequency.

  In addition, a low-pass filter that removes an error component due to drift of the Doppler frequency is provided.

  The calculation unit removes an error component caused by Doppler frequency drift.

  As described above, an elevator signal transmission device that wirelessly transmits signals using signal transmission devices provided in each of the elevator car and the machine room, using at least millimeter wave carriers having different transmission frequencies and reception frequencies. Since one or more signals are transmitted in both directions, the effect of transmitting and receiving can be obtained even if the transmission distance of the signal fluctuates. In addition, it is possible to transmit a large amount of data at a high speed corresponding to future multimedia.

  In addition, the signal transmission device is installed in the upper and lower parts of the car, and at least one signal transmission system is installed in each of the uppermost part and the lowermost part of the elevator shaft, and the signal transmission system is duplicated. Even so, the effect of transmitting and receiving can be obtained. In addition, it is possible to transmit a large amount of data at a high speed corresponding to future multimedia.

  In addition, the signal transmission device combines a digital data signal, a video signal, and an audio signal into a microwave, and converts the microwave received from the microwave transmitter into a millimeter wave and receives the microwave. Since the millimeter wave transmitter / receiver that converts the converted millimeter wave into microwave again and the microwave receiver that demodulates the microwave received from the millimeter wave transmitter / receiver again into a digital data signal, a video signal, and an audio signal, Even if the transmission distance of the signal fluctuates, the effect of being able to transmit and receive is obtained. In addition, it is possible to transmit a large amount of data at a high speed corresponding to future multimedia.

  Further, since the microwave receiving unit receives and follows the change in the frequency of the microwave from the millimeter wave transmitting / receiving unit, the effect of being able to transmit / receive even if the transmission distance of the signal changes is obtained. In addition, it is possible to transmit a large amount of data at a high speed corresponding to future multimedia.

  In addition, since the digital data signal is converted into the VHF frequency and synthesized with the video signal and the audio signal, an effect of transmitting and receiving can be obtained even if the transmission distance of the signal varies. In addition, it is possible to transmit a large amount of data at a high speed corresponding to future multimedia.

  Further, since the video signal and the audio signal are NTSC signals and are converted to the VHF TV channel frequency and then synthesized with the digital data signal, the transmission and reception effect can be obtained even if the transmission distance of the signal varies. In addition, it is possible to transmit a large amount of data at a high speed corresponding to future multimedia.

  In addition, since the transmission channel and the reception channel of the VHF TV channel are the same, it is possible to transmit and receive even if the signal transmission distance varies. In addition, it is possible to transmit a large amount of data at a high speed corresponding to future multimedia.

  In addition, the VHF TV channel has a channel in which the transmission channel and the reception channel are different from each other by one or more channels, so that it is possible to prevent interference within the same signal transmission apparatus.

  In addition, since an operation unit that measures the received power of the microwave received by the microwave receiving unit and calculates the raising / lowering distance of the cage from the received power is provided, the effect of accurately calculating the raising / lowering distance of the cage can be obtained. .

  In addition, since the Doppler frequency of the reception frequency of the microwave received by the microwave receiving unit is measured and the calculation unit for calculating the raising / lowering speed of the cage and the raising / lowering distance of the basket from the Doppler frequency is provided, An effect of accurately calculating the lifting distance can be obtained.

  Further, since the low-pass filter that removes the error component due to the drift of the Doppler frequency is provided, an effect of accurately calculating the raising / lowering speed and the raising / lowering distance of the cage can be obtained.

  Further, since the calculation unit removes an error component due to Doppler frequency drift, an effect of accurately calculating the raising / lowering speed and the raising / lowering distance of the cage can be obtained.

Embodiment 1 FIG.
1 is a block diagram showing an elevator signal transmission apparatus according to Embodiment 1 of the present invention. In the figure, reference numeral 1 denotes a signal transmission apparatus according to the present invention. 11 is a microwave transmitter that synthesizes a digital data signal and an analog signal (audio signal, video signal, etc.) and transmits them to the millimeter wave transmitter / receiver, and 12 converts the microwave from the microwave transmitter 11 into millimeter waves. A millimeter wave transmission / reception unit that converts the transmitted and received millimeter waves into microwaves and transmits the microwaves to the microwave reception unit. 13 separates the microwaves from the millimeter wave transmission / reception unit 12 into digital data signals and analog signals and demodulates them. A microwave receiving unit 14 is a reference oscillator that serves as a reference for frequency-converting a digital data signal into a VHF band or a VHF band signal into a digital data signal, and constitutes a signal transmission device 1.

  Reference numeral 111 denotes a data encoder, 112 denotes a phase modulation unit, 113 denotes a TV modulator, 114 denotes a signal synthesizer, 115 denotes a microwave oscillator, and 116 denotes an up-converter. These components constitute the microwave transmission unit 11. Further, 121 is an up-converter, 122 is a millimeter-wave oscillator, 123 is a circulator, 124 is an antenna, and 125 is a down-converter. 131 is a signal distribution unit, 132 and 135 are down converters, 133 is a carrier wave recovery unit, 134 is a microwave oscillator, 136 is a TV tuner, and 137 is a data decoder. Yes.

  FIG. 2 is a block diagram showing an elevator equipped with the signal transmission device 1 in FIG. In the figure, 1a is a machine room side signal transmission device, 1b is a basket side signal transmission device, and is equivalent to the signal transmission device in FIG. Reference numeral 2a denotes a machine room side control panel for controlling the machine room side signal transmission device 1a, which is further connected to an upper control room. 2b is a car side control panel for controlling the car side signal transmission device, 3 is a motor, 4 is a machine room composed of the control panel 2a, motor 3, etc., and 5 is an elevator car.

  Here, the antenna 124 is a directional antenna such as a horn antenna or a planar antenna, and has a single polarization characteristic. The radiation directivity is a narrow angle to prevent multipath fading in the elevator shaft. However, the radiation directivity may be wide-angle as long as the millimeter wave transceiver 12 has a function of preventing multipath fading.

  Further, the up-converter 121 and the down-converter 125 are millimeter-wave band frequency converters for transmission and reception. At present, the characteristics of a band-pass filter for isolating transmission / reception frequencies and the millimeter-wave shown in FIG. In consideration of the characteristics of the waveband mixer, the operating frequencies of the microwave transmission unit 2 and the microwave reception unit 3 that are intermediate frequency bands are set to the 2 GHz band.

  Further, the millimeter wave oscillator 122 uses direct oscillation by a GUNN diode or the like in order to achieve cost reduction. However, at present, the temperature characteristic of the oscillation frequency is not good and frequency drift occurs. Therefore, in order to improve the temperature characteristics of the oscillator itself, a temperature detection element such as a thermistor is used to detect the ambient temperature of the oscillator, and the supply voltage to the GUNN diode is changed according to the temperature to suppress the frequency drift. ing.

  Next, the operation will be described based on FIG. 1 and FIG. First, a digital data signal from the machine room side control panel 2a is input to the data encoder 111 of the microwave transmission unit 11 of the machine room side signal transmission device 1a through an interface such as TTL, and the phase modulation unit 112 outputs the reference oscillator 14 Phase modulated with respect to frequency. At this time, the differential encoding for transmitting “0” and “1” at the phase change point is performed by the data encoder 111 in order to reliably perform phase modulation as a countermeasure against multipath fading. On the other hand, the video signal and the audio signal are analog transmission, and are input to the TV modulator 113 by a video signal based on the NTSC signal. The TV modulator 113 converts it into a 90 MHz band VHF signal corresponding to 1 to 2 channels of the TV channel, and combines the power with the above-mentioned phase-modulated data signal and the combiner 114. The frequency is converted to an intermediate frequency in the 2 GHz band by the microwave oscillator 115 and the up converter 116 in the 2 GHz band. This intermediate frequency is transmitted to the millimeter wave transceiver 12.

  The intermediate frequency transmitted from the microwave transmission unit 11 is converted into a millimeter-wave band frequency by the up-converter 121 and the millimeter-wave oscillator 122, and is transmitted from the antenna 124 via the circulator 123 to the opposite car-side signal transmission device 1b. Transmit to antenna 124. When the millimeter-wave band radio wave transmitted from the machine room side signal transmission device 1 a is received by the antenna 124, the frequency is again converted to the intermediate frequency of 2 GHz band by the down converter 125 and transmitted to the microwave receiver 13.

  The intermediate frequency in the 2 GHz band received from the millimeter wave transmitting / receiving unit 12 is distributed by the distributor 131 of the microwave receiving unit 13 and divided into digital data signal demodulation and analog signal demodulation. The downconverter 132, the carrier wave reproducing unit 133, and the microwave oscillator 134 reproduce the intermediate frequency transmitted with reference to the frequency of the reference oscillator 14. Since the above-described frequency variation of the millimeter wave oscillator 122 is reflected in the intermediate frequency obtained by the receiving unit, the frequency variation is fed back to the carrier wave reproducing unit 133 as a voltage so as to automatically follow the variation of the transmission frequency.

  The down-converter 135 performs frequency conversion from the intermediate frequency of 2 GHz band received using the recovered carrier from the carrier recovery unit 133 to the video signal of VHF band. This is because the millimeter wave oscillator 122 on the other side generates a frequency drift, and the frequency-converted VHF signal is also shifted in frequency, and the video signal cannot be reproduced. The TV tuner 136 extracts a video signal and an audio signal as a video signal from the VHF signal. Further, the data decoder 137 performs differential decoding and extracts a digital data signal.

  Here, 1ch and 2ch, which are different in transmission and reception, are assigned to the VHF frequency corresponding to the TV channel in order to prevent interference within the same apparatus. Further combinations may be possible, and the same channel may be assigned depending on the performance of the TV tuner.

  The operation described above is transmission from the machine room side signal transmission device 1a to the cage side signal transmission device 1b. At the same time, signal transmission from the cage side signal transmission device 1b to the machine room side signal transmission device 1a is performed. Is also done.

  As shown in FIG. 2, this apparatus is used in one set of two machines. As shown in FIG. 4, another set of signal transmission devices 1c and 1d are further provided at the lower part of the cage 5 and the lowermost part of the elevator shaft. It may be installed to double the signal transmission system. At this time, the upper signal transmission apparatuses 1a and 1b and the lower signal transmission apparatuses 1c and 1d use millimeter wave carriers having different frequencies in order to prevent mutual cross modulation.

  As described above, according to the first embodiment, since a signal is transmitted bidirectionally using a millimeter wave carrier wave, an effect that transmission / reception can be performed even if the transmission distance of the signal varies is obtained. In addition, an effect of transmitting a large amount of data at a high speed corresponding to future multimediaization can be obtained.

Embodiment 2. FIG.
In the present embodiment, in the signal transmission device as in the first embodiment, the microwave receiver 13 detects the Doppler frequency, and calculates the lifting speed and the lifting distance of the cage from the detected Doppler frequency. Further, a method for removing an error component due to Doppler frequency drift will be described.

In the millimeter wave transmission used in the signal transmission apparatus according to the present invention, the elevator car moves up and down at high speed, so that the millimeter wave carrier undergoes a Doppler shift expressed by the following equation. The Doppler frequency fd is expressed by the following equation (1), where the elevator lifting speed is v, the carrier frequency is fc, and the speed of light in vacuum is c ₀ (3 × 10 ⁸ m / sec).

  Since the maximum lift speed v of the elevator assumed in the present invention is 670 m / min, the Doppler frequency fd is about 22.2 kHz at the maximum when the carrier wave frequency fc of the millimeter wave is 60 GHz, and about 2.8 kHz at the maximum of 76 GHz. It becomes. Thus, when calculating the elevator lifting speed, the Doppler frequency fd is detected and taken into consideration. However, as described above, a frequency drift occurs in the millimeter wave oscillator.

  From the above equation (1), the raising / lowering speed of the car is expressed as equation (2).

しかし、上述のようにドリフトによる誤差が存在するため、昇降速度は図６（ａ）に示すような関係にある。図６（ａ）から、昇降速度ｖは式（３）のように表される。

However, since an error due to drift exists as described above, the ascending / descending speed has a relationship as shown in FIG. From FIG. 6A, the ascending / descending speed v is expressed as shown in Expression (3).

  If the carrier frequency fc is constant, α can be regarded as a constant, the ascending / descending speed is a linear function of the Doppler frequency, and a detection value to which an error component β due to drift is applied. Thus, in order to calculate an accurate ascending / descending speed, it is necessary to remove an error component β due to drift and detect an accurate Doppler frequency.

  FIG. 5 is a block diagram showing a means for detecting a Doppler frequency and an arithmetic unit used in the signal transmission apparatus according to Embodiment 2 of the present invention. In the figure, 1321 is a band-pass filter (BPF), 1322 is a variable gain (AGC) amplifier, 1323 is a distributor, and 1324 is a frequency converter, and these constitute the down converter 132 in FIG. Reference numeral 1331 denotes a 90 ° phase shifter, 1332 denotes a distributor, 1333 denotes a loop filter, and 1334 denotes an integrator. These components constitute the carrier recovery unit 133 in FIG. Further, 15 is a low-pass filter that removes the short-term drift of the detected Doppler frequency, 16 is a short-term drift and long-term drift that cannot be removed by the low-pass filter 15, and the speed of raising and lowering the cage is determined from the Doppler frequency. An arithmetic unit that performs arithmetic operations, and includes an A / D converter 161, a digital signal processor (DSP) 162, a microcomputer (μ-COM) 163, and a D / A converter 164.

  Next, the operation will be described. 1 passes through the bandpass filter (BPF) 1321 and the variable gain (AGC) amplifier 1322 in FIG. 5 and is transmitted to the carrier wave by the following costas loop. Is divided into two by the distributor 1332 and input to the down converter 135 in FIG. 1 to demodulate the signal in the VHF band.

  The Costas loop divides a signal into two by a distributor 1323, and a signal oscillated from the microwave oscillator 134 is converted to a low frequency by a frequency converter 1324, 1325 using a distributor 1332, 90 ° phase shifter 1331. Convert. The frequency-converted two signals are multiplied by a multiplier 1334 to detect a phase difference between the received carrier wave and the signal of the microwave oscillator 134 and converted into a control voltage of the microwave oscillator 134 by the loop filter 1333. In this feedback system, the received carrier wave is reproduced. Here, a low-pass filter (LPF) may be inserted between the frequency converters 1324 and 1325 and the multiplier 1334. However, in the present invention, this LPF is omitted and the tracking range for the received carrier wave is widened. ing.

  Here, the Doppler frequency obtained from the outputs of the frequency converters 1324 and 1325 has a characteristic as shown in FIG. As shown in the figure, there are error components due to drift in addition to the true value of the Doppler frequency, and error components due to drift include long-term drift and short-term drift. The long-term drift is a slow frequency change due to a temperature variation or the like, and the short-term drift is an instantaneous frequency change due to vibration or the like. Therefore, in order to calculate an accurate ascending / descending speed, it is necessary to remove an error component due to drift of the detected Doppler frequency.

  First, a low-pass filter (LPF) is used to remove short-term drift. Here, the anti-aliasing LPF 15 is used to prevent the sampling frequency of the A / D converter 161, which will be described later, from returning. However, since short-term drift and long-term drift that are frequencies within the passband of the anti-aliasing LPF 15 cannot be removed, it is left to subsequent processing.

  A signal from which a short-term drift of a frequency equal to or higher than the passband of the anti-aliasing LPF 15 is removed is input to the A / D converter 161 of the arithmetic unit 16 and sampled. The sampling period is at least twice the maximum Doppler frequency, but may be changed as necessary. The sampled signal is subjected to frequency analysis (FFT) using a digital signal processor (DSP) 162 to calculate the frequency component and its amplitude in the sampling signal. At this time, the digital signal processor (DSP) 162 may be omitted, and the microcomputer (μ-COM) 163 may perform high-speed computation. On the basis of the calculated frequency component, the microcomputer (μ-COM) 163 obtains the ascending / descending speed based on the above formula (2), and obtains the ascending / descending distance (cage position) by integrating the ascending / descending speed. These calculation results are sent to the control panel or control room of the elevator and used for controlling the elevator car.

  Here, the microcomputer (μ-COM) 163 removes short-term drift that could not be removed by the anti-aliasing LPF 15 by an arithmetic process such as a smoothing process. For long-term drift removal, for example, a map showing the relationship between temperature and frequency is created in advance, such as a frequency of a (Hz) at a temperature of A ° C and a frequency of b (Hz) at a temperature of B ° C. Then, the map is corrected by calculation processing.

  Furthermore, if the gain of the variable gain amplifier 1322 is controlled using the D / A converter 164 so that the calculated amplitude value is constant, the reception power of the microwave (millimeter wave) can be made constant. This is effective in preventing multipath fading.

  As described above, according to the second embodiment, by removing the drift component of the Doppler frequency, the raising / lowering speed and the raising / lowering distance (the position of the basket) of the cage can be accurately calculated.

  In order to further improve the detection accuracy of the Doppler frequency, it is preferable to use a highly stable millimeter wave oscillator.

  Alternatively, the car side signal transmission device and the machine room side signal transmission device may independently detect the Doppler frequency, collect the calculated ascending / descending speed and ascending / descending distance data, and perform integrated processing in the control room.

  In the second embodiment, the raising / lowering speed of the car is obtained from the Doppler frequency and the raising / lowering distance is calculated by integrating the raising / lowering speed. However, the position of the car may be obtained from the received power of the microwave. As described above, the gain of the variable gain amplifier 1322 is controlled in order to make the amplitude of the Doppler frequency constant. This feedback amount depends on the millimeter wave received by the car or the machine room (and the micro wave converted from the millimeter wave). This corresponds to the received power of the received radio wave. Therefore, for example, when the car is in the position of the raising / lowering distance A (m), the received power is a (V), and at the position of the raising / lowering distance B (m), the received power is b (V). And a map showing the relationship between the received power and the position of the car can be estimated from this map.

It is a block diagram which shows the elevator signal transmission apparatus by Embodiment 1 of this invention. It is a block diagram which shows the elevator carrying the elevator signal transmission apparatus by Embodiment 1 of this invention. It is a figure which shows the example of a characteristic of a millimeter wave band mixer. It is a block diagram which shows another elevator signal transmission apparatus by Embodiment 1 of this invention. It is a block diagram which shows the means and calculating part which detect the Doppler frequency used with the signal transmission apparatus by Embodiment 2 of this invention. It is a figure which shows the characteristic of the Doppler frequency detected with the elevator signal transmission apparatus by Embodiment 2 of this invention. It is a block diagram which shows the conventional elevator signal transmission system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1a, 1b Signal transmission apparatus, 11 Microwave transmission part, 12 Millimeter wave transmission / reception part, 13 Microwave reception part, 14 Reference oscillator, 15 Low-pass filter, 16 Calculation part, 2a, 2b Control panel, 3 Motor, 4 Machine Room, 5 baskets

Claims (5)

A microwave transmission unit that is provided in either the elevator car or the machine room and synthesizes the first digital data signal, the first video signal, and the first audio signal and converts them into a first microwave. The first microwave received from the microwave transmission unit is converted into a first millimeter wave and transmitted from the antenna, and the second millimeter wave received by the antenna is converted into a second microwave. A millimeter wave transmitter / receiver, and a microwave receiver that demodulates the second microwave received from the millimeter wave transmitter / receiver into a second digital data signal, a second video signal, and a second audio signal, respectively. A first signal transmission device;
And the microwave transmission unit, the millimeter wave transmission / reception unit, the microwave reception unit, and the microwave reception unit provided in a different side from the first signal transmission device in the elevator car or the machine room A first calculation unit that measures the Doppler frequency of the reception frequency of the second microwave received by the unit and calculates the elevator speed and distance of the elevator car from the Doppler frequency, and a transmission frequency An elevator signal comprising a second signal transmission device that wirelessly transmits signals to and from the first signal transmission device using millimeter wave carriers having different reception frequencies from each other Transmission equipment.   The elevator signal transmission device according to claim 1, wherein the second signal transmission device includes a low-pass filter that removes an error component due to drift of the Doppler frequency.   The elevator signal transmission apparatus according to claim 1, wherein the first calculation unit removes an error component due to drift of the Doppler frequency.     The elevator signal transmission device according to claim 1, wherein the microwave reception unit follows the frequency change of the second microwave received from the millimeter wave transmission / reception unit. The second calculation in which the first signal transmission device or the second signal transmission device measures the reception power of the second microwave received by the microwave reception unit and calculates the lift distance of the cage from the reception power. The elevator signal transmission apparatus according to claim 1, further comprising a unit.

Images