Abstract: A frequency-modulated continuous wave (FMCW) millimeter-wave (MMW) radar system. Preferred embodiments operate within a frequency range between about 77 and 81 GHz (wavelengths between about 3.846 mm and 3.304 mm). The MMW frequency in these embodiments is increased or decreased (“chirped ”) in a very linear fashion over some or all of this operating frequency range. Over the chirp period, the time derivative of the transmit frequency, df/dt, is held constant. In the time ? it takes for the radar's transmit signal, moving at the speed of light c, to travel from the antenna to a target at a range R and return back to the antenna (?=2R/c), the transmitter's output frequency will have moved by an amount (df/dt)*?. Thus, the more distant the reflecting target, the greater the two-way signal time of flight and consequently the greater the frequency change.

Abstract: A radar sensing system for a vehicle includes transmit and receive pipelines. The transmit pipeline includes transmitters able to transmit radio signals. The receive pipeline includes receivers able to receive radio signals. The received radio signals include transmitted radio signals that are reflected from an object. The transmitters phase modulate the radio signals before transmission, as defined by a first binary sequence. The receive pipeline comprises at least one analog to digital converter (ADC) for sampling the received radio signals. The first binary sequence is defined by least significant bit (LSB) outputs from the at least one ADC.

Abstract: A millimeter wave radio link in which the transceivers have most of its components fabricated on a single chip or chipset of a small number of semiconductor chips. The chip or chipsets when mass produced is expected to make the price of millimeter wave radios comparable to many of the lower-priced microwave radios available today from low-cost foreign suppliers. Preferred embodiments of the present invention operate in the range of about 3.5 Gbps to more than 10 Gbps. The transceivers of a preferred embodiment are designed to receive binary input data at an input data rate in 10.3125 Gbps and to transmit at a transmit data rate in of 10.3125 Gbps utilizing encoded three-bit data symbols on a millimeter carrier wave at E-Band frequencies. Preferred embodiments include an averaging technique that greatly improves bit error rates. A constellation averaging technique is utilized to improve bit error rates.

Abstract: A phase modulated continuous wave radar system comprising a radar control system utilizing a Pseudo Random Bit Sequence (PRBS) as a long modulation code with simultaneous autocorrelation and cross-correlation interference resistance. the transmitter is co-sited with the receiver, the receiver can be given prior knowledge of the specific transmitted code that it is correlating to. This prior knowledge, which is not accessible in general to bi-static systems such as GPS and cell phone technology, allows for increased randomization of cyclic code structures in monostatic radar systems.

Abstract: A radar sensing system for a vehicle includes transmit and receive pipelines. The transmit pipeline includes transmitters able to transmit radio signals. The receive pipeline includes receivers able to receive radio signals. The received radio signals include transmitted radio signals that are reflected from an object. The transmitters phase modulate the radio signals before transmission, as defined by a first binary sequence. The receive pipeline comprises at least one analog to digital converter (ADC) for sampling the received radio signals. The first binary sequence is defined by least significant bit (LSB) outputs from the at least one ADC.

Abstract: A radar sensing system for a vehicle includes transmit and receive pipelines. The transmit pipeline includes transmitters able to transmit radio signals. The receive pipeline includes receivers able to receive signals. The received signals are transmitted signals that are reflected from an object. The transmit pipeline phase modulates the signals before transmission, as defined by a first binary sequence. The receive pipeline comprises an analog to digital converter (ADC) for sampling the received signals. The transmit pipeline includes a pseudorandom binary sequence (PRBS) generator for outputting a second binary sequence of bits with an equal probability of 1 and 0. The first binary sequence is defined by least significant bit (LSB) outputs from the ADC and the second binary sequence of bits. The first binary sequence comprises a truly random unbiased sequence of bits with an equal probability of 1 and 0.

Abstract: A radar sensing system for a vehicle includes transmit and receive pipelines. The transmit pipeline includes transmitters able to transmit radio signals. The receive pipeline includes receivers able to receive signals. The received signals are transmitted signals that are reflected from an object. The transmit pipeline phase modulates the signals before transmission, as defined by a first binary sequence. The receive pipeline comprises an analog to digital converter (ADC) for sampling the received signals. The transmit pipeline includes a pseudorandom binary sequence (PRBS) generator for outputting a second binary sequence of bits with an equal probability of 1 and 0. The first binary sequence is defined by least significant bit (LSB) outputs from the ADC and the second binary sequence of bits. The first binary sequence comprises a truly random unbiased sequence of bits with an equal probability of 1 and 0.

Abstract: A millimeter wave radio link in which the transceivers have most of its components fabricated on a single chip or chipset of a small number of semiconductor chips. The chip or chipsets when mass produced is expected to make the price of millimeter wave radios comparable to many of the lower-priced microwave radios available today from low-cost foreign suppliers. Preferred embodiments of the present invention operate in the range of about 3.5 Gbps to more than 10 Gbps. The transceivers of a preferred embodiment are designed to receive binary input data at an input data rate in 10.3125 Gbps and to transmit at a transmit data rate in of 10.3125 Gbps utilizing encoded three-bit data symbols on a millimeter carrier wave at E-Band frequencies.

Abstract: A millimeter wave radio transceiver having all or substantially all of its components fabricated on a single chip or chipset of a small number of semiconductor chips. The chip or chipsets when mass produced is expected to make the price of millimeter wave radios comparable to many of the lower-priced microwave radios available today from low-cost foreign suppliers. Transceivers of the present invention operate in the range of about 1 Gbps to more than 10 Gbps. The transceiver of a preferred embodiment is designed to receive binary input data at an input data rate in 10.3125 Gbps and to transmit at a transmit data rate in of 10.3125 Gbps utilizing encoded three-bit data symbols on a millimeter carrier wave at a millimeter wave nominal carrier frequency in excess of 70 GHz.

Abstract: A high data rate millimeter wave radio adapted to receive an binary input data at an input data rate in excess of 3.5 Gbps and to transmit at a transmit data rate in excess of 3.5 Gbps utilizing encoded three-bit data symbols on a millimeter carrier wave at a millimeter wave nominal carrier frequency, defining a carrier wavelength and period, in excess of 70 GHz with differential phase-shift keying utilizing eight separate phase shifts. Preferred embodiments of the invention can support many of the high data rate standards including the following group of protocols or standards: SONET OC-96 (4.976 Gbps); 4xGig-E (5.00 Gbps); 5xGig-E (6.25 Gbps); OBSAI RP3-01 (6.144 Gbps); 6xGig-E (7.50 Gbps); Fibre Channel 8GFC (8.5 Gbps); SONET OC-192 (9.952 Gbps); Fibre Channel 10GFC Serial (10.52 Gbps) and 10 GigaBit Ethernet.

Abstract: A communication system and method that combines with direct high data rate links at least one content distribution networks with a number of base stations of at least one cellular communication networks. In preferred embodiments the high data rate direct communication links between the content distribution networks and the base stations include millimeter wave radio links and the cellular communication networks are provided with third or fourth generation communication equipment providing data rates in excess of 40 Mbps. In a preferred embodiment millimeter wave links operating at data rates in the range of about 1.25 Gbps or greater in frequency ranges of within the range of 71 GHz to 86 GHz provide communication channels between base stations and points of presence of the content distribution network.

Abstract: A high bandwidth, low latency middle-mile core communications network providing low-cost and high-speed communications among the users of the network. Embodiments of the invention include a number of network access points located at a number of spaced apart sites. At least some of these network access points in the network are in communication with each other via millimeter radio links with microwave backup links. In preferred embodiments the millimeter radio links include two millimeter radios, one transmitting in the frequency range of 71-76 GHz and receiving in the frequency range if 81 to 86 GHz and the other radio transmitting in the frequency range of 81-86 GHz and receiving in the frequency range if 71 to 76 GHz.

Abstract: A short range millimeter wave surface imaging radar system. The system includes electronics adapted to produce millimeter wave radiation scanned over a frequency range of a few gigahertz. The scanned millimeter wave radiation is broadcast through a frequency scanned transmit antenna to produce a narrow transmit beam in a first scanned direction (such as the vertical direction) corresponding to the scanned millimeter wave frequencies. The transmit antenna is scanned to transmit beam in a second direction perpendicular to the first scanned direction (such as the horizontal or the azimuthal direction) so as to define a two-dimensional field of view. Reflected millimeter wave radiation is collected in a receive frequency scanned antenna co-located (or approximately co-located) with the transmit antenna and adapted to produce a narrow receive beam approximately co-directed in the same directions as the transmitted beam in approximately the same field of view.

Abstract: A long range millimeter wave imaging radar system. Preferred embodiments are positioned to detect foreign object debris objects on surface of the runway, taxiways and other areas of interest. The system includes electronics adapted to produce millimeter wave radiation scanned over a frequency range of a few gigahertz. The scanned millimeter wave radiation is broadcast through a frequency scanned antenna to produce a narrow scanned transmit beam in a first scanned direction (such as the vertical direction) defining a narrow, approximately one dimensional, electronically scanned field of view corresponding to the scanned millimeter wave frequencies. The antenna is mechanically pivoted or scanned in a second scanned direction perpendicular to the first scanned direction so as to define a two-dimensional field of view.

Abstract: A long range millimeter wave imaging radar system. Preferred embodiments are positioned to detect foreign object debris objects on surface of the runway, taxiways and other areas of interest. The system includes electronics adapted to produce millimeter wave radiation scanned over a frequency range of a few gigahertz. The scanned millimeter wave radiation is broadcast through a frequency scanned antenna to produce a narrow scanned transmit beam in a first scanned direction (such as the vertical direction) defining a narrow, approximately one dimensional, electronically scanned field of view corresponding to the scanned millimeter wave frequencies. The antenna is mechanically pivoted or scanned in a second scanned direction perpendicular to the first scanned direction so as to define a two-dimensional field of view.

Abstract: A high bandwidth, low latency middle-mile core communications network providing low-cost and high-speed communications among the users of the network. Embodiments of the invention include a number of network access points located at a number of spaced apart sites. At least some of these network access points in the network are in communication with each other via millimeter radio links with microwave backup links. In preferred embodiments the millimeter radio links include two millimeter radios, one transmitting in the frequency range of 71-76 GHz and receiving in the frequency range if 81 to 86 GHz and the other radio transmitting in the frequency range of 81-86 GHz and receiving in the frequency range if 71 to 76 GHz. In these preferred embodiments each millimeter wave radio is equipped with an antenna designed to produce a millimeter wave beam with an angular spread of less than two degrees. A high-speed switch is located at each network access point.

Abstract: A short range millimeter wave surface imaging radar system. The system includes electronics adapted to produce millimeter wave radiation scanned over a frequency range of a few gigahertz. The scanned millimeter wave radiation is broadcast through a frequency scanned transmit antenna to produce a narrow transmit beam in a first scanned direction (such as the vertical direction) corresponding to the scanned millimeter wave frequencies. The transmit antenna is scanned to transmit beam in a second direction perpendicular to the first scanned direction (such as the horizontal or the azimuthal direction) so as to define a two-dimensional field of view. Reflected millimeter wave radiation is collected in a receive frequency scanned antenna co-located (or approximately co-located) with the transmit antenna and adapted to produce a narrow receive beam approximately co-directed in the same directions as the transmitted beam in approximately the same field of view.

Abstract: A high bandwidth, low latency middle-mile, last mile core communications network providing low-cost and high-speed communications among the users of the network. Embodiments of the invention include a number of network access points located at a number of spaced apart sites. At least some of these network access points in the network are in communication with each other via wireless radio links. The network provides backhaul communication between at least one communication switching center and a number of base stations.

Abstract: A millimeter wave radio transceiver having all or substantially all of its components fabricated on a single chip or chipset of a small number of semiconductor chips. The chip or chipsets when mass produced is expected to make the price of millimeter wave radios comparable to many of the lower-priced microwave radios available today from low-cost foreign suppliers. Transceivers of the present invention operate in the range of about 1 Gbps to more than 10 Gbps. The transceiver of a preferred embodiment is designed to receive binary input data at an input data rate in 10.3125 Gbps and to transmit at a transmit data rate in of 10.3125 Gbps utilizing encoded three-bit data symbols on a millimeter carrier wave at a millimeter wave nominal carrier frequency in excess of 70 GHz.

Abstract: A millimeter wave imaging system. The system includes one or more millimeter wave frequency scanning antenna for collecting frequency dependent beams of millimeter wave radiation from a narrow one-dimensional field of view and millimeter wave amplifier components for amplifying the millimeter wave radiation collected by each antenna. The system includes a beam-former that separates the amplified radiation to produce frequency dependent signals corresponding to the frequency dependent beams. The beam-former includes delay lines, a millimeter wave lens, and an array of millimeter wave power detectors for detecting the power in each frequency dependent beam. A sampling circuit reads out the frequency dependent signals to produce a one-dimensional image of the antenna field of view. A two dimensional image of a target may be obtained by moving the target (or having the target move) across the field of view of the scanning antenna or by moving the antenna in order to scan its line of focus over the target.