RU2247470C1 - Personal computer - Google Patents

Abstract

FIELD: computer equipment hardware for global computer network.

SUBSTANCE: novelty is that proposed personal computer incorporates provision for wireless access to input of service provider computer due to newly introduced transceiver device incorporating sine-wave oscillator, frequency synthesizer, transmission channel incorporating switch, carrier amplifier, single-pole signal shaper, output amplifier, antenna, pulse shaper, second switch and data request signal circuit, as well as receiving channel incorporating receiving unit, radio-frequency amplifier, double-pole amplitude detector, inverter, delay circuit, pulse shaper, register, and two decoders. Data signal transmission and reception speed is 26 Mbit/s.

EFFECT: enhanced data exchange speed.

1 cl, 5 dwg

Description

The invention relates to hardware devices of computer equipment for use in a single global computer network.

The prototype adopted a personal computer type IBM PC [1], containing a system unit, monitor, keyboard input devices and a mouse, output devices, a printer and a modem. The modem, connecting the serial port / COM1 or COM2 / of the system unit to the telephone line, allows the user of a personal computer to exchange information with the outside world in full duplex mode [2 p.280], using two carrier frequencies, transmitting and receiving information simultaneously. A prerequisite for a computer working on the Internet is the presence of telephone lines connecting the modem to the PBX, and communication lines from the PBX to the modem of the service provider's computer. The disadvantage of the prototype is the need for telephone lines of communication, the absence of which deprives access to the Internet, and the low speed of transmission, reception of information.

The purpose of the invention is to provide wireless access from a personal computer to the computer of the service provider and increase the speed of transmission, reception of information.

The technical result is a wireless access of a personal computer of a user to a computer of a service provider with a high-speed exchange of information signals.

The technical result is achieved by using the transmission functions, receiving an information signal in the computers of the user and the service provider instead of the modem of the radio transmission device, receiving with a narrow band on the air / less than 1000 Hz / and transmitting speed, receiving information 25 Mbps. When registering a name and receiving a password in the organization of the service provider, the user of the personal computer receives from it the value of the carrier frequency of his transmission device, reception and the value of the carrier frequency at which the service provider will conduct radio communications. The switches in the transmission device, the reception, the user sets the value of these frequencies. The transmission and reception device is connected with a standard cable with a 25-pin connector to the serial port / COM1 or COM2 / of the computer system unit.

The essence of the invention is that in a personal computer including a system unit, a monitor, a keyboard, a mouse and a printer, a transmission device is introduced, comprising a sinusoidal oscillation generator and a frequency synthesizer, a transmission channel and a reception channel, the transmission channel contains a key, a carrier amplifier frequencies, a shaper of a single-band signal, an output amplifier, an antenna, a pulse shaper, a second key and an information request signal circuit, a reception channel contains a reception unit, a radio frequency amplifier, a bipolar amp smart detector, inverter, delay element, summing amplifier, pulse shaper, register, first and second decoders.

The structural diagram of a personal computer in figure 1, a functional diagram of a transmission device, reception in figure 2, a circuit diagram of a bipolar amplitude detector in figure 3, the signal spectrum from the transmission channel in figure 4, timing diagrams of operation in figure 5.

The personal computer / Fig. 1/ includes a system unit 1, a monitor 2, a keyboard 3, a mouse 4, a printer 5 and a transmission device, reception 6.

The transmission device, receiving 6/2 / includes a serially connected oscillator 7 and a frequency synthesizer 8, a transmission channel containing a first key 9 connected in series, a carrier frequency amplifier 10, a single-band signal driver 21 and an output amplifier 12, an antenna, a driver 13 pulses, the second switch 14 and the information request signal circuit 15, includes a reception channel comprising a reception unit 16, a radio frequency amplifier 17, a bipolar amplitude detector 18, an inverter 19, a delay element 20, a summing amplifier spruce 21, generate 22 pulses, register 23, first 24 and second 25 decoders. Generator 7 of sinusoidal oscillations, synchronized by clock pulses from the system unit 1 through pin 8 of the connector / RS-232 / serial port, generates sinusoidal oscillations with the stability of the clock generator of system unit 1. A frequency synthesizer 8 generates sinusoidal oscillations of the carrier frequency of the transmission channel to the input first key 9. The value of the carrier frequency is given to the user of the home computer by the organization of the service provider when registering a name and receiving a password. The frequency is set by the user in the synthesizer 8 frequencies switch. Alternatively, 400 MHz is received. From the second output, the frequency synthesizer 8 produces sinusoidal oscillations with a period corresponding to the period of the pulse from the pulse shaper 13. The input of the pulse shaper 13 receives information pulses from the connector 2 of the serial port of the system unit 1. The frequency of sinusoidal oscillations from the second output of the synthesizer 8 frequencies is 25 MHz, the oscillation period is 40 ns. From the third output, a frequency synthesizer 8 generates sinusoidal oscillations of the carrier frequency at which the service provider's computer is in radio communication with the home computer. The frequency is communicated to the user and set by him in the synthesizer of 8 frequencies. This frequency is necessary for detecting a single-band signal [3, p.146] in the reception channel. From the fourth output, the frequency synthesizer 8 generates control clock pulses of the corresponding frequency for register operation 23. The pulse shaper 13 generates from the incoming pulses from the serial port of the system unit 1 pulses of the corresponding amplitude and duration equal to the period of the sinusoidal oscillation / 40 ns / arriving at the signal input of the key 14. The pulse from the shaper 13 pulses arrives at the control input of the key 14, opens it for the duration of its duration / 40 ns /.

During the open state, the key 14 passes one sine wave to the output, which performs amplitude modulation of the carrier frequency / 400 MHz / in block 11. The presence of a sine wave represents the presence of a pulse, its absence is the absence of a pulse. The spectrum of the amplitude-modulated signal / Fig. 4/ consists of a carrier and two side frequencies: lower and upper. One of the side frequencies and the carrier itself are in the information sense redundant. The shaper of a single-band signal consists of a ring modulator and a band-pass filter [4, p.235]. By the method of double balanced modulation and filtering of one of the side bands, block 11 generates a single-cavity signal. In block 11, the carrier frequency is suppressed, and the band-pass filter filters the upper side frequency of 425 MHz / 400 + 25 /. Information on the codes is carried by the lower side frequency of 375 MHz / 400-25 /. The stability of the carrier is determined by the stability of the clock in the system unit 1. With the stability of the generator 7 in 10 ^{-6, the} lower side frequency in the air takes the band ± 375 Hz, i.e. 750 Hz, which will allow 1300 home computers connected in the 1 MHz band connected to the service provider's computer, the clock frequency of which can be 10 ^-7 , and the occupied radio band of the service provider's computer with the home computer will be an order of magnitude smaller. The output amplifier 12 amplifies the radio signal to the value required for radiation into the ether. The information request signal circuit 15 generates and issues a CTS / Clear To Send / acknowledgment signal to the 5th pin of the serial port connector of system unit 1 (5, p. 250].

The acknowledgment signal RTS / Request To Send / from the system unit 1 from pin 4 of the connector / R-232 / is fed to the first control input of key 9 and opens it. The carrier frequency from the first output of the 8-frequency synthesizer goes to amplifier 10. Replacing the pulses with sinusoids before broadcasting allows you to take advantage of the sinusoidal signal: sinusoidal oscillation is less susceptible to noise distortion, modulation of a highly stable sinusoidal frequency multiple to it in frequency, sinusoidal oscillation using single-band transmission makes it possible to get the narrowest band on the air, which, in turn, reduces the effect of noise on the sinusoidal Igna / interference spectrum is wide, and at a fraction of 750 Hz have a negligible part of energy interference /, upon receiving codes, which are presented in unit sinusoids, it is possible to recover all signals are subjected to noise distortion.

When receiving information, the radio signal about the antenna enters the block 16 of the reception, which is a selector of the decimeter range channels / ACS /. Block 16 represents the first half of SKD-24 [6, p.132] and includes an input circuit, a preliminary radio frequency amplifier, and a VT2 mixer [6, Fig. 4.2] / without a local oscillator circuit and an IF filter, available in SKD, is used from the frequency converter -24 /. Block 16 performs reception in the UHF range and has electronic tuning for receiving a radio signal from a transmission device of a service provider's computer. The radio frequency allocated by the pre-amplifier bandpass filter through the communication loop is fed to the input of the emitter of the VT2 mixer. From the third output of the 8-frequency synthesizer, sinusoidal oscillations with a frequency corresponding to the frequency of the transmission device in the service provider's computer arrive at the mixer. The signal from the collector of the mixer VT2, which is the output signal of block 16, is input to the amplifier 17 of the radio frequency, amplified to the required value, and fed to the input of the bipolar amplitude detector 18, made according to the scheme [7, p. 112], its circuit diagram in Fig. 3 . Diode D1 selects the positive envelope (Fig. 5, diagram 6) of the modulating sinusoidal signal, diode D2 already selects the envelopes of the positive half-sine waves from diagram 7 /, diode D3 selects the envelopes of the negative half-sine wave (diagram 8). From the first output of block 18, positive half-sine waves through delay element 20 / perform a delay of 20 ns, i.e. for 0.5 period of the sinusoid / arrive at the first input of the summing amplifier 21 / chart 9 /. From the second output of block 18, negative half-sine waves through an inverter 19, which changes the phase of negative half-sine waves by 180 ° / diagram 10 /, i.e. to positive half-sine waves, arrive synchronously / and almost in phase / with positive half-sine waves from the delay element 20 to the second input of the summing amplifier 21.

The total signal in the form of an enlarged positive half-sine wave from block 21 is fed to the input / diagram 11 / of the pulse shaper 22. An inverter 19, a delay element 20, and a summing amplifier 21 are used to reconstruct code signals that are affected by interference. The half-sinusoids of one sinusoidal oscillation are bipolar, so the effect of interference on them is not the same. The half-sine wave which is in antiphase with the amplitude of the interference is distorted more. A half-sine wave of a different polarity is less distorted or not affected at all. Moreover, the distorted half-sine wave remains in shape closer to the half-sine wave than to a signal of a different kind. To create conditions conducive to the recovery of code signals, before transmission, each information pulse / arriving at block 13 / is replaced by a sinusoidal oscillation. To restore the distorted code signals / sine / positive half sine from the first output of block 18 is delayed by a half-cycle / 20 ns /, and the phase of the negative half-sine / from the second output of block 18 / is changed by inverter 19 by 180 ° / 3 /, diagrams 9 and 10 figure 5. The inputs of the summing amplifier 21 come synchronously two unipolar half-sine waves. If one of them is distorted or absent, one half-sine wave is sufficient for block 21 to output the corresponding signal to the pulse shaper 22, which generates a pulse in polarity, amplitude, and duration identical to the code pulse in system unit 1. Code signals are also sent to register 23, from the outputs of which in parallel to the decoder 24 and the second decoder 25. The decoder 24 with the arrival of the code of the corresponding command issues a signal U ₃ to the second control input of the first key 9, which closes it. The carrier frequency does not enter block 10, the transmission of information is interrupted. The decoder 25 with the arrival of the code of the corresponding command decrypts it and through the input terminal 22 of the connector / Fig.2/ sends to the serial port of the system unit 1 call R1 from the computer of the service provider. The speed of transmission and reception of information by a device for transmitting and receiving 25 Mbps.

To connect the service provider's computer with one home computer, he needs to have one identical transmission and reception device. To communicate with many home computers, a similar device with several transmission and reception channels is required, a generator 7 and a frequency synthesizer 8 are sufficient and one.

The operation of the transmission device, reception.

The device is connected with a standard cable / RS-232 / with a 25-pin connector to the serial port in the system unit 1 of the computer. The cable uses seven lines [2, p. 283, 5, p. 250]

Line assignment Connector pin TCD data transfer from a computer port 2 RHD information reception by the system unit 1 3 RTS acknowledgment signal from the system unit port, or a request for information transfer 4 STS clear for transmission, or acknowledgment signal from the device’s transmission channel 5 GND grounding 7 - clock signals for synchronization of the generator 7 8 R1 call the user's computer from the computer of the service provider 22

When transmitting information, code messages framed with start, control and stop bits [8, p. 155] from the serial port of the system unit 1 are fed to the input of the pulse shaper 13 in the transmission channel. Formed by the duration and amplitude of the pulse opens the key 14, passing one sinusoid with a frequency of 25 MHz / 40 ns / to the second input of the shaper 11 of a single-band signal. The sine wave modulates the carrier frequency in amplitude, diagrams 2-5 in FIG. 5. Block 11 provides a lower side frequency of 375 MHz, amplified in block 12 and radiated into the air. The radio signals of the code messages from the transmission channel of the service provider's computer are received by block 16, where the lower side frequency is mixed in the mixer with the carrier signal from the third output of the 8 frequency synthesizer. The output signal, which is the sum of the voltages of the single-band signal and the carrier, is amplified in the radio frequency amplifier 17 and fed to the input of the bipolar amplitude detector 18. From the first output of block 18, the positive half-sine wave is delayed by 20 ns by a delay element 20 and fed to the first input of the summing amplifier 21. From the second the output of block 18, the negative half-sine wave is inverted in the inverter 19 and the positive half-sine wave is fed to the second input of block 21. Shaper 22 pulses upon receipt of signals from block 21 of the form it generates pulses at the output that correspond to the pulses used by the system unit 1 in polarity, amplitude, and duration, which through pin 3 of the RHD connector enter the serial port of the computer system unit. The transmission device, the reception can be made of two special microcircuits, included in the computers will provide wireless Internet access.

Sources of information

1. A.KENIN. Tutorial on IBM PC. Ekaterinburg. 2001, p. 10-39.

2. WINN L. Roche. The Winn Roche Technical Support Bible. Minsk, 1992, p. 280-283.

3. Radio communications, broadcasting, television broadcasting, ed. A.D. Fortushenko, M. 1981, p. 146.

4. Radio transmitting devices, M. S. Shumilin and others, M. 1981, S. 234, 235.

5. A. Borzenko. IBM PC: device, repair, upgrade. Second edition. M. 1997, p. 249-263.

6. Brodsky M.A. Television color image. Minsk, 1988, p.132, fig. 4.2.

7. Handbook of Broadcasting, ed. A.V. Vykhodtsa, Kiev, 1981. p. 112, Fig. 81.

8. Pyatibratov A.P. Gudyno L.P., Kirichenko A.A. Computing Systems, Networks and Telecommunications, ed. A.P. Pyatibratov, ed. 2, M. 2002, p. 155.

Claims (1)

A personal computer containing a system unit, a monitor, the inputs and outputs of which are connected to the corresponding outputs and inputs of the system unit, a keyboard, a mouse, the inputs and outputs of which are connected to the corresponding outputs and inputs of the system unit, and a printer, the inputs of which are connected to the corresponding outputs a system unit, characterized in that a transmission and reception device is inserted into it, including a sinusoidal oscillation generator and a frequency synthesizer connected in series, a transmission channel, comprising the first key, the carrier amplifier, the single-band signal shaper, the output amplifier and the antenna, the pulse shaper and the second key, the output of which is connected to the second input of the single-band signal shaper, and the information request signal circuit, the input of which is connected to the output of the first key, including a receiving channel containing a serially connected receiving unit, a radio frequency amplifier, a bipolar amplitude detector, a delay element, the input of which is connected the first output of the bipolar amplitude detector, the summing amplifier, the first input of which is connected to the output of the delay element, the pulse shaper and the register, contains an inverter, the input of which is connected to the second output of the bipolar amplitude detector, and the output is connected to the second input of the summing amplifier, the first and second decoders, the inputs of which are bitwise parallel connected to the outputs of the register, the output of the first decoder is connected to the second control input of the first key in the transmission channel, the outputs are synthesized A number of frequencies are connected: the first and second in the transmission channel, respectively, to the signal inputs of the first and second keys, the third and fourth in the reception channel, respectively, to the second input of the reception unit, to the control input of the register, the information input of the transmission device, reception is the input of the pulse generator of the transmission channel, connected to the corresponding output of the serial port of the system unit, the information output is the output of the pulse shaper of the receive channel connected to the corresponding input of the same the serial port of the system unit, the control inputs of the transmission, reception are the input of the sine wave generator and the first control input of the first key in the transmission channel, connected to the corresponding outputs of the same serial port of the system unit, the control outputs of the transmission, reception are the output of the information request signal circuit and the output of the second decoder of the receive channel, connected to the corresponding inputs of the same serial port of the computer system unit.

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