Steerable beamforming system

Communications – electrical: acoustic wave systems and devices – Transmitter systems – With beam forming – shaping – steering – or scanning

Reexamination Certificate

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C367S103000

Reexamination Certificate

active

06721235

ABSTRACT:

BACKGROUND OF THE INVENTION
In numerous application there is a need to perform beamforming operations to acquire spatial information regarding a particular region of interest. Various systems have been developed to perform such beamforming operations which frequently depend upon the particular applications.
One application involves beamsteering and/or beamforming in medical ultrasound systems used to image internal organs. For undersea acoustic mine-field reconnaissance and mine hunting applications, high-resolution imaging sonars are needed for clutter rejection, obstacle avoidance, and identification of possible mines. needed for use in a diver's hands, in a remote imaging sonar on an unmanned undersea vehicle, or with a small surface-craft sonar.
SUMMARY OF THE INVENTION
The present invention relates to a high-resolution, three-dimensional imaging system based on a large-area electronically steerable two-dimensional array. The large aperture provides a beamwidth less than 0.3°. Beamforming, or beamsteering, can be performed using time-domain delay-and-sum operations. A delay-and-sum beamformer allows a 2D array to “look” for signals propagating in a particular direction. By adjusting the delays associated with each element of the array, the array's directivity can be electronically steered toward the source of radiation. By systematically varying the beamformer's delays and its shading along a 2D imaging plane, a 2D scan response of the array can be measured and resulting 2D images representing the 3D radiation sources can be created. The proposed system can provide continuous real-time 128-by-128-pixel scanned images throughout a 14° field of view. The proposed delay-and sum beamforming approach allows target range information to be obtained from the time-of-flight calculations. When a target area is identified by the proposed electronically steerable sonar system, the beamforming electronics can be adjusted to zoom-in to a smaller field-of-view for high-resolution imagery.
Components of the system include a large-area, low-insertion loss and high-bandwidth sparse array, a 32-channel beamforming processor, a bank of low-noise amplifiers, and CDP FIR filters for baseband signal conversion. The beamforming electronics and FIR filters use low-power, high-throughput charge-domain-processing (CDP) technology. At a 40 MHZ clock rate, the beamformer can provide a continuous computation throughput of 10.2 billion operations per second and a delay update rate of 28 billion bits/s and dissipate approximately 1 W of electric power. A technology comparison (shown in Table 1) of the present low-power, 2D beamformer, a commonly-used microprocessor and a digital signal processor (DSP) the Texas Instruments' TMS320C6201 processor, demonstrates the more than an order-of magnitude power savings offered by a preferred embodiment of the invention.
In a preferred embodiment of the invention uses a shading procedure to increase the ratio of the main lobe relative to the side lobes to provide a difference of at least 20 dB, and preferably of at least 25 dB to provide the desired image quality. The small size of the array, such as a 10 cm×10 cm system, or alternatively a 20 cm×20 cm system, can provide a low power, high resolution system suitable for use by divers or small vessels, for example.
For a preferred embodiment of the invention having a system where multiple beams have to be processed in parallel to achieve a higher frame rate system, the resulting electronics can rapidly become both bulky and costly as the number of beams increases. The present invention relates to a single-chip multiple beamforming processor based on a time-multiplexed delay generation architecture. The integrated circuit combines programmable delays with a sequentially addressable digital delay selection which results in a compact, low-power multiple beamforming processor.
In general, this parallel beamforming can be performed on digital or analog signals. Applications of this system include medical ultrasound imaging, sonar and radar. With the reduction in size, weight and power, these systems can be included in portable low power battery operated systems.


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