Method and apparatus for transmitting and receiving time-domain radar signals

Description

BACKGROUND OF THE INVENTION

Radar systems are widely used to detect objects and to measure relative distances and speeds. Better, faster, smaller, lighter, more accurate, reliable and rugged radar systems are needed.

SUMMARY OF THE INVENTION

According to an embodiment of the invention, a radar system comprises a radar transmitter, radar receiver or radar transceiver circuit on a printed circuit board. An antenna is also on the printed circuit board and connected to the circuit on the printed circuit board. Power, trigger or data feed-lines are connected to the circuit. The antenna comprises vee dipole antenna arms on the printed circuit board. The vee dipole antenna arms further comprise plural spaced copper pads on the printed circuit board and discreet surface mount resistors connected between the copper pads.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 schematically shows feed-point circuitry and discrete resistively loaded antenna arms on a printed circuit board.

FIG. 2 schematically shows feed-point electronics driven by feed-lines which are traces printed on a long connecting circuit board.

FIG. 3 is a detail view of a feed-line circuit board.

FIG. 4 schematically shows printed circuit boards configured according to one embodiment of the present invention stacked to create an array of radar channels.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 schematically shows feed-point circuitry and discrete resistively loaded antenna arms printed on a circuit board.

Apparatus for generating, transmitting, receiving and detecting radar signals, particularly for the purpose of time-domain microwave radar systems, are generally indicated by the numeral 1.

A printed circuit board 3 has a miniaturized time-domain impulse radar channel 5 containing a transmitter circuit or a receiver circuit or a miniaturized transceiver circuit 7 with surface mount components. Radiating and receiving antennas 11 transmit or receive the radar signals. Antenna 11 is fabricated on the printed circuit board 3. The time-domain impulse radar channel 5 with the receiver circuit or the transmitter circuit or transceiver circuit is included on the same printed circuit board 3, located in close proximity to the feed-point 13 of the antenna 11. A preferred antenna 11 is a resistive vee dipole having discrete resistors 17 soldered to spaced copper pads 15 deposited on the printed circuit board 3. The entire length of the antenna 11 radiates and receives signals. The resistors 17 between the copper pads 15 make the short antenna 11 operate as a long, resistive dipole antenna.

The invention is applicable to any type of antenna geometry or resistive loading. The invention is most effective with a vee-dipole geometry used with a tapered (linear or exponential) resistive profile. That minimizes antenna resonances, which cause unwanted reflections and clutter in the transmitted or received radar impulses.

The invention eliminates the need for a transmission line which would be carrying high-frequency, high-bandwidth signals between the antennas and the pulse generator or receiving circuitry. That results in fewer artifacts due to reflections in the transmission line, lower noise, and more controlled and repeatable signals. By locating all microwave signals, including the antennas 11, on a single printed circuit board 3, the signal properties can be much better controlled. Feed-lines 19 are connected to the circuit 7 for conducting power, triggers, and/or data.

Circuit boards 3 of the invention can be stacked to create an array of radar channels. The invention can be realized on a thin substrate, including but not limited to film, polycarbonate, or thin FR4 to minimize radar cross section and the effects of dispersion. FR4 is a substrate typically used for ruggedized printed circuits and has a polymeric fiberglass and epoxy structure. The printed circuit boards 3 can be fabricated with specific outlines to minimize radar cross sections in both the traveling wave direction and the orthogonal directions.

FIG. 2 schematically shows feed-point electronics 1 driven by feed-lines 19 which are printed traces 21 on a long connecting circuit board.

FIG. 3 is a detail view of feed-lines 21 on a circuit board 23 which is a middle layer between two ground layers.

Connections to the printed circuit board 3 are provided via traces 21 printed on a long strip 23 of circuit board material. Circuit board strip 23 can be made of the same material as circuit board 3. In one embodiment, the strip 23 of the circuit board is an extension of the same circuit board 3 which mounts the transceiver 7 and antenna assembly 11. That is desirable, as it allows the system electronics (not shown) to be located at a distance from the feed-point 13 of the antenna 11. The electronics could be located behind radar absorbing material or far enough away as to place them outside the range gate of the receiver. By fabricating the feed-lines as traces 21 on a printed circuit board 23, the impedance can be very carefully controlled along the length of the feed-line traces 21, reducing clutter-causing reflections in the received signal. It is also cheaper and easier to manufacture than using conventional feed-lines, such as co-axial cables.

In a preferred embodiment, as shown in the FIG. 3 detail, feed-line traces 21 are formed in an insulator layer 25 are sandwiched between two thin, parallel conductive layers or ground planes which are connected to each other by through vias 31 at periodic intervals.

The invention provides the inclusion of the transmitter or receiver circuitry 7 on the same printed circuit board 3 as the antennas 11. The invention results in radar signals that have fewer reflection artifacts, lower noise, and is more reliably and less expensively manufactured than the prior art.

FIG. 4 schematically shows printed circuit boards configured according to one embodiment of the present invention stacked to create an array of radar channels. Array 40 comprises circuit boards 401-1-401-N. Each of printed circuit boards 401-1-401-N includes miniaturized transceiver circuit 7 and antenna 11. By stacking circuit boards 401-1-401-N, array 40 is created having multiple radar channels.

While the invention has been described with reference to specific embodiments, modifications and variations of the invention may be constructed without departing from the scope of the invention, which is defined in the following claims.