Advanced downhole waveform interpretation

What is claimed is: 1. A computer-implemented method of processing a measured ultrasonic response waveform to determine a value indicative of whether a sealing medium acoustic impedance is within a designated range, the method comprising: transmitting an ultrasonic signal from an ultrasonic inspection tool toward the well casing from within the well casing; generating, via an ultrasonic transducer, a measured response waveform resulting from the transmitted ultrasonic signal, wherein the ultrasonic inspection tool comprises the ultrasonic transducer; processing the measured response waveform to determine an arrival time for a first reflection from the well casing; generating a plurality of simulated response waveforms corresponding to the arrival time, a set of candidate acoustic impedances for the sealing medium in the annulus, a set of candidate well casing thicknesses, a set of candidate annulus thicknesses, and a set of candidate properties comprising acoustic impedances for one or more interfaces between the sealing medium and a ground formation surrounding the annulus; identifying a best-fit simulated response waveform from the plurality of simulated response waveforms that best matches the measured response waveform; determining, based on the identified best-fit simulated response waveform, the value indicative of whether the sealing medium acoustic impedance is within the designated range; and outputting the value indicative of whether a sealing medium acoustic impedance is within the designated range to a user via an output device. 2. The computer-implemented method of claim 1 , further comprising: processing a portion of the measured response waveform to determine an approximate thickness of the well casing; and selecting the set of candidate well casing thicknesses based on the approximate thickness of the well casing. 3. The computer-implemented method of claim 1 , further comprising processing a portion of the measured response waveform to determine a transducer impulse response for an ultrasonic transducer used to generate the measured response waveform, and wherein each of the plurality of simulated response waveforms is based on the transducer impulse response. 4. The computer-implemented method of claim 3 , wherein generating each of the plurality of simulated response waveforms comprises: calculating amplitudes for simulated echo waves returning to the ultrasonic transducer from the well casing and at least one interface between the sealing medium in the annulus and the ground formation surrounding the annulus; generating corrected amplitudes and pulse shapes for the simulated echo waves by correcting the amplitudes and pulse shapes for the simulated echo waves to account for multi-dimensional propagation effects including diffraction, refraction, and resulting beam size at a transducer plane of the ultrasonic transducer; generating a first simulated waveform based on the corrected amplitudes and pulse shapes; and convolving the first simulated waveform with the transducer impulse response to generate the respective simulated response waveform. 5. The computer-implemented method of claim 3 , further comprising: calculating a differential signal between the measured response waveform and the best-fit simulated response waveform; calculating a corrected transducer impulse response for the ultrasonic transducer by correcting the transducer impulse response based on the differential signal; generating a second-iteration plurality of simulated response waveforms based on the corrected transducer impulse response and corresponding to the arrival time, a second-iteration set of candidate acoustic impedances for the sealing medium surrounding the well casing, a second-iteration set of candidate well casing thicknesses, a second-iteration set of candidate annulus thicknesses, and a second-iteration set of candidate properties for at least one interface between the sealing medium and the ground formation surrounding the annulus; and identifying a second-iteration best-fit simulated response waveform from the second-iteration plurality of simulated response waveforms that best matches the measured response waveform, wherein the value indicative of whether the sealing medium acoustic impedance is within the designated range is determined based on the identified second-iteration best-fit simulated response waveform. 6. The computer-implemented method of claim 5 , wherein generating each of the second-iteration plurality of simulated response waveforms comprises convolving a simulated response waveform with the corrected transducer impulse response to generate the respective simulated response waveform of the second-iteration plurality of simulated response waveforms. 7. The computer-implemented method of claim 1 , wherein each of the plurality of simulated response waveforms is based on reflection of the ultrasonic signal from an inner surface of the well casing, reflection of the ultrasonic signal from an interface between the well casing and the sealing medium in the annulus, reflection of the ultrasonic signal from at least one other interface between the sealing medium in the annulus and the ground formation surrounding the annulus, and multiple reverberations of the ultrasonic signal within the well casing. 8. The computer-implemented method of claim 1 , further comprising: generating a confidence value based on deviation between the best-fit simulated response waveform and the measured response waveform; identifying a best fit well casing thickness of the set of candidate well casing thicknesses; identifying a best-fit sealing medium acoustic impedance of the set of candidate acoustic impedances for the medium in the annulus; and analyzing the best-fit well casing thickness, the best-fit sealing medium acoustic impedance, and the confidence value in combination to produce the value indicative of whether the sealing medium acoustic impedance is within the designated range. 9. The computer-implemented method of claim 1 , further comprising identifying a best-fit sealing medium acoustic impedance of the set of candidate acoustic impedances for the medium in the annulus, wherein the value indicative of whether the sealing medium acoustic impedance is within the designated range is based on the identified best-fit sealing medium acoustic impedance. 10. The computer-implemented method of claim 8 , wherein the value indicative of whether the sealing medium acoustic impedance is within the designated range is determined for a plurality of depths and a plurality of azimuth angles. 11. A system for processing a measured ultrasonic response waveform to determine a value indicative of whether a sealing medium acoustic impedance is within a designated range, the system comprising: an ultrasonic inspection tool that transmits an ultrasonic signal toward the well casing from within the well casing, the ultrasonic inspection tool comprising an ultrasonic transducer that generates a measured response waveform resulting from the transmitted ultrasonic signal; an output device; a processor; a tangible memory storing non-transient instructions executable by the processor to cause the processor to: process a measured response waveform resulting from an ultrasonic signal transmitted toward the well casing from within the well casing to determine an arrival time for a first reflection from the well casing; generate a plurality of simulated response waveforms corresponding to the arrival time, a set of candidate acoustic impedances for the sealing medium in the annulus, a set of candidate well casing thicknesses, a set of candidate annulus thicknesses, and a set of candidate propertie