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A method and apparatus for transmitting and receiving RF signals for broadband communications using power lines as communication medium. A super-heterodyne structure is used to translate the signals from one frequency to another so as to avoid interference sources, which may corrupt the communicatio

A method and apparatus for transmitting and receiving RF signals for broadband communications using power lines as communication medium. A super-heterodyne structure is used to translate the signals from one frequency to another so as to avoid interference sources, which may corrupt the communication signals. In the heterodyne structure, a plurality of local oscillators are used to mix the local oscillator signals with the communication signals for frequency translation. A plurality of frequency filters are used to filtered out unwanted signals. The communication signals are imparted onto or received from the power lines via couplers operatively connected to modems.

대표청구항 ▼

What is claimed is: 1. A power line communications (PLC) modem for translating a broadband radio frequency (RF) output signal used for the transmission of communication data in broadband communications using power lines as a communication medium so as to avoid frequencies associated with interferin

What is claimed is: 1. A power line communications (PLC) modem for translating a broadband radio frequency (RF) output signal used for the transmission of communication data in broadband communications using power lines as a communication medium so as to avoid frequencies associated with interfering signals, said modem comprising: a modulator, responsive to communication data, for generating a modulated signal that is modulated by said communication data; a first filter, responsive to the modulated signal, for providing a first filtered modulated signal; a first multiplier, responsive to the first filtered modulated signal and to a first oscillator signal, for generating a first mixed signal based upon mixing the first filtered modulated signal and the first oscillator signal; a second filter, responsive to the first mixed signal, for providing a filtered first mixed signal; a second oscillator signal having a selectable operating frequency over an operating frequency range; a second multiplier, operatively connected to the second filter and responsive to the second oscillator signal, for generating a second mixed signal based upon mixing the filtered first mixed signal and the second oscillator signal; a radio-frequency filter, responsive to the second mixed signal, for providing a filtered broadband RF output signal; and means, operatively connected to the RF filter, for coupling the filtered broadband RF output signal to at least one of the power lines; whereby the broadband RF output signal has a selectable operating frequency so as to be able to avoid frequencies associated with interfering signals. 2. The modem of claim 1, further comprising an amplifier, operatively connected to the second multiplier and the second filter, for amplifying the filtered first mixed signal prior to the second multiplier generating the second mixed signal based upon mixing the filtered first mixed signal and the second oscillator signal. 3. The modem of claim 1, further comprising an amplifier, operatively connected to the coupling means and the RF filter, for amplifying the filtered RF output signal prior to said coupling means coupling the filtered RF output signal to one of the power lines. 4. The modem of claim 1, also capable of reception of broadband communications from the power lines, said modem further comprising: means, coupled to said at least one power line, for receiving an RF input signal from said at least one power line; a further RF filter, responsive to the received RF input signal, for providing a filtered RF input signal; a third multiplier, responsive to the filtered RF input signal and a third oscillator signal, for generating a third mixed signal based upon mixing the filtered RF input signal and the third oscillator signal; a third filter, responsive to the third mixed signal, for providing a filtered third mixed signal; a fourth multiplier, operatively connected to the third filter and responsive to a fourth oscillator signal, for providing a fourth mixed signal based upon mixing the filtered third mixed signal and the fourth oscillator signal; a fourth filter, responsive to the fourth mixed signal, for providing a filtered fourth mixed signal; and a demodulator, responsive to the filtered fourth mixed signal, for generating further communication data. 5. The modem of claim 4, further comprising an amplifier, operatively connected to the receiving means and further RF filter, for amplifying the received RF input signal prior to said further RF filter providing the filtered RF input signal based on the received RF input signal. 6. The modem of claim 4, further comprising an amplifier, operatively connected to the third filter and the fourth multiplier, for amplifying the filtered third mixed signal prior to said fourth multiplier generating the fourth mixed signal based upon mixing the filtered third mixed signal and the fourth oscillator signal. 7. The modem of claim 4, wherein the RF input signal has a frequency range substantially equal to 9.8 MHz to 47.8 MHz. 8. The modem of claim 7, wherein the third oscillator signal has a frequency range substantially equal to 149.8 MHz to 187.8 MHz, and the filtered third mixed signal has a frequency substantially equal to 140 MHz with a bandwidth of 4 MHz. 9. The modem of claim 8, wherein the fourth oscillator signal has a frequency substantially equal to 149.8 MHz, and the filtered fourth mixed signal has a frequency substantially equal to 9.8 MHz with a bandwidth of 4 MHz. 10. The modem of claim 4, wherein the RF input signal has a frequency range substantially equal to 3.75 MHz to 48.75 MHz. 11. The modem of claim 10, wherein the third oscillator signal has a frequency range substantially equal to 73.75 MHz to 118.75 MHz, and the filtered third mixed signal has a frequency substantially equal to 70 MHz with a bandwidth of 2.5 MHz. 12. The modem of claim 11, wherein the fourth oscillator signal has a frequency substantially equal to 73.75 MHz, and the filtered fourth mixed signal has a frequency substantially equal to 3.75 MHz with a bandwidth of 2.5 MHz. 13. The modem of claim 1, wherein the first oscillator signal has a frequency substantially equal to 73.75 MHz. 14. The modem of claim 13, wherein the modulated signal has a frequency substantially equal to 3.75 MHz with a bandwidth of 2.5 MHz and the filtered first mixed signal has a frequency substantially equal to 70 MHz with a bandwidth of 2.5 MHz. 15. The modem of claim 14, wherein the second oscillator signal has a frequency range substantially equal to 73.75 MHz to 118.75 MHz, and the filtered RF output signal has frequency range substantially equal to 3.75 MHz to 48.75 MHz with a bandwidth of 2.5 MHz. 16. The modem of claim 1, wherein the first oscillator signal has a frequency substantially equal to 149.8 MHz. 17. The modem of claim 16, wherein the modulated signal has a frequency substantially equal to 9.8 MHz with a bandwidth of 4 MHz and the filtered first mixed signal has a frequency substantially equal to 140 MHz with a bandwidth of 4 MHz. 18. The modem of claim 17, wherein the second oscillator signal has a frequency range substantially equal to 149.8 MHz to 187.8 MHz, and the filtered RF output signal has frequency range substantially equal to 9.8 MHz to 47.8 MHz with a bandwidth of 4 MHz. 19. A method of broadband communications for translating a broadband radio frequency (RF) signal used for transmitting communication data using power lines as a communication medium so as to avoid frequencies associated with interfering signals, said method comprising the steps of: generating a modulated signal that is modulated by the communication data; filtering the modulated signal for providing a first filtered modulated signal; mixing the first filtered modulated signal and a first oscillator signal for providing a first mixed signal; filtering the first mixed signal for providing a filtered first mixed signal; providing a second oscillator signal having a selectable operating frequency over an operating frequency range; mixing the filtered first mixed signal and the second oscillator signal for providing a second mixed signal; filtering the second mixed signal for providing a filtered broadband RF output signal; and coupling the filtered broadband RF output signal to at least one of the power lines, whereby the broadband RF output signal has a selectable operating frequency so as to be able to avoid frequencies associated with interfering signals. 20. The method of claim 19 further comprising the step of amplifying the filtered first mixed signal prior to mixing the filtered first mixed signal and the second oscillator signal. 21. The method of claim 19, further comprising the step of amplifying the filtered RF output signal prior to said coupling. 22. A method of broadband communications for translating a broadband radio frequency (RF) signal used for receiving communication data using power lines as a communication medium so as to avoid frequencies associated with interfering signals, said method comprising the steps of: receiving a broadband RF input signal indicative of the communication data from at least one of the power lines via coupling; filtering the received RF input signal for providing a filtered RF input signal; mixing the filtered RF input signal with a first oscillator signal for providing a first mixed signal; filtering the first mixed signal for providing a filtered first mixed signal; providing a second oscillator signal having a selectable operating frequency over an operating frequency range; mixing the filtered first mixed signal and the second oscillator signal for providing a second mixed signal; filtering the second mixed signal for providing a filtered second mixed signal; and obtaining the communication data based upon demodulating the filtered second mixed signal, whereby the broadband RF input signal has a selectable operating frequency so as to be able to avoid frequencies associated with interfering signals. 23. The method of claim 22, further comprising the step of amplifying the received RF input signal prior to filtering the received RF signal. 24. The method of claim 22, further comprising the step of amplifying the filtered first mixed signal prior to mixing the filtered first mixed signal with a second oscillator signal.