Motion detection using ping-based and multiple aperture doppler ultrasound

We claim: 1 . A method of measuring a velocity of objects moving within a region of interest, comprising: transmitting a first unfocused semicircular ultrasound wavefront pulse from a first transmit aperture; receiving echoes of the first wavefront pulse at a first receive aperture; storing in-phase values of the received echoes; storing quadrature values of the received echoes; and evaluating the in-phase and quadrature values to determine a magnitude and a direction of motion of objects within the region of interest relative to the first transmit aperture or the first receive aperture. 2 . The method of claim 1 wherein the transmit aperture and the receive aperture are located on a common transducer array. 3 . The method of claim 1 further comprising: receiving echoes of the first wavefront pulse at a second receive aperture that is separate from the first receive aperture, and storing in-phase and quadrature values of the received echoes. 4 . A method of producing an ultrasound image indicating motion, the method comprising: retrieving a first data set from a non-volatile digital memory device, the first data comprising position and orientation information of a transmit aperture; retrieving a second data set from a non-volatile digital memory device, the second data set comprising a series of echo magnitude values resulting from echoes of a sequence of transmitted Doppler ping signals; detecting Doppler shift frequencies within at least a portion of the second data set based on a first set of Doppler detection parameters; determining a position of at least one moving reflector based on a second set of beamforming parameters, wherein at least one parameter has a value different than a value used during a live imaging session in which the echo data was captured. 5 . The method of claim 4 , wherein the first set of parameters or the second set of parameters includes one or more of: a transmit aperture definition, a receive aperture definition, a test segment, a predominant direction axis, a relative movement threshold value to characterize a fast movement value over a slow movement value, a Doppler motion estimation algorithm, a speed-of-sound assumption, one or more weighting factors, a de-convolution filtering value, a matched filtering value, a calibration data value, or a transmission data value. 6 . The method of claim 4 , wherein the Doppler detection parameters include at least one of a test segment definition, a predominant direction axis definition, a minimum speed threshold value, and a Doppler motion estimation algorithm. 7 . The method of claim 4 , wherein the beamforming parameters include at least one of a speed-of-sound value, a weighting factor, an applied filter type, a probe calibration datum, and a datum describing an ultrasound transmit signal.