Non-intrusive detection of pipe parameters using selected guided acoustic wave modes

What is claimed is: 1. A method for measuring a parameter relating to a pipe using guided acoustic wave modes, comprising: receiving, at a computing system, data corresponding to an acoustic signal; wherein the data are obtained by transmitting an excitation pulse at a specified frequency and detecting the resulting acoustic signal using at least one acoustic transducer attached to an outer surface of a wall of a pipe; and wherein the specified frequency is within a range of 10 kilohertz (kHz) to 2 megahertz (MHz); analyzing, via the computing system, the data to identify guided acoustic wave modes within the acoustic signal; wherein the guided acoustic wave modes comprise a circumferential shear horizontal (C-SH) acoustic wave mode that travels within the wall of the pipe and at least one of: a circumferential Lamb type (C-LT) acoustic wave mode that travels within a near-surface region of the wall of the pipe; or a cavity (CA) acoustic wave mode that travels within a cavity of the pipe; and determining, via the computing system, a measurement for at least one parameter relating to the pipe based on the identified guided acoustic wave modes; wherein the at least one parameter comprises at least one of a multiphase flow condition, a liquid level, a volume fraction of water, oil, and/or gas, an amount of solids deposition, an identification of solids, or a flow rate within the pipe; and wherein determining the measurement comprises: calibrating the measurement using the C-SH acoustic wave mode; and determining the measurement based on a phase velocity and/or an amplitude of the at least one of the C-LT acoustic wave mode or the CA acoustic wave mode. 2. The method of claim 1 , wherein the at least one parameter comprises the multiphase flow condition within the pipe; and wherein determining the measurement for the multiphase flow condition comprises determining a volume fraction of a gas within a liquid flowing through the pipe based on the phase velocity and/or the amplitude of the CA acoustic wave mode. 3. The method of claim 1 , wherein the at least one parameter comprises the liquid level within the pipe; and wherein determining the measurement for the liquid level comprises at least one of: determining a liquid level with the pipe based on the phase velocity and/or the amplitude of the C-LT acoustic wave mode; or determining a gas pocket distribution within the pipe based on the phase velocity and/or the amplitude of the CA acoustic wave mode. 4. The method of claim 1 , wherein the at least one parameter comprises the amount of solids deposition within the pipe; wherein the solids comprise primarily wax/scale and the pipe is filled with liquid; and wherein determining the measurement for the amount of solids deposition comprises determining an amount of wax/scale that is deposited on an inner surface of the wall of the pipe based on the phase velocity and/or the amplitude of the at least one of the C-LT acoustic wave mode or the CA acoustic wave mode. 5. The method of claim 1 , wherein the at least one parameter comprises the amount of solids deposition within the pipe; wherein the solids comprise primarily wax/scale and the pipe is filled with gas; and wherein determining the measurement for the amount of solids deposition comprises determining an amount of wax/scale that is deposited on an inner surface of the wall of the pipe based on the phase velocity and/or the amplitude of the C-LT acoustic wave mode. 6. The method of claim 1 , wherein the at least one parameter comprises the amount of solids deposition within the pipe; wherein the solids comprise primarily sand; and wherein determining the measurement for the amount of solids deposition comprises determining an amount of sand present within the pipe based on the phase velocity and/or the amplitude of the at least one of the C-LT acoustic wave mode or the CA acoustic wave mode. 7. The method of claim 1 , wherein the at least one parameter comprises the flow rate within the pipe; and wherein the method comprises: receiving, at the computing system, data corresponding to acoustic signals obtained from acoustic transducers positioned at corresponding nodes along a length of the pipe, wherein each node comprises at least one acoustic transducer for transmitting excitation pulses and detecting acoustic signals; analyzing, via the computing system, the data to identify the guided acoustic wave modes within the acoustic signals; and determining, via the computing system, the measurement for the flow rate by: analyzing the data corresponding to the phase velocity of the CA acoustic wave mode within each node to detect a pattern of flow for each node; and calculating a change in the flow rate within the pipe based on a combination of known separation distances between each node and the calculated pattern of flow for each node. 8. The method of claim 1 , wherein the at least one parameter comprises the flow rate within the pipe; and wherein the method comprises: receiving, at the computing system, data corresponding to acoustic signals obtained from acoustic transducers positioned at corresponding nodes along a length of the pipe, wherein each node comprises at least one acoustic transducer for transmitting an excitation pulse and detecting a corresponding acoustic signal; analyzing, via the computing system, the data to identify a phase velocity of guided acoustic wave modes within the acoustic signal at each node; and determining, via the computing system, the measurement for the flow rate based on the phase velocities of the CA acoustic wave modes within the acoustic signals by: cross-correlating data corresponding to the phase velocities of the CA acoustic wave modes at neighboring nodes to identify a correlation between the phase velocities and to calculate a propagation time for the correlated phase velocities between the neighboring nodes; and calculating the flow rate within the pipe based on a combination of known separation distances between the neighboring nodes and the calculated propagation time for the correlated phase velocities. 9. The method of claim 1 , comprising determining, at the computing system, the specified frequency at which the at least one acoustic transducer is to transmit the excitation pulse based on known properties of the pipe through which the acoustic signal propagates by: receiving data corresponding to a circumferential guided acoustic wave mode propagating through the wall of the pipe; analyzing the data to calculate a dispersion curve for the circumferential guided acoustic wave mode; identifying one or more guided acoustic wave modes of interest; selecting an excitation frequency range to experimentally determine the specified frequency at which to transmit the one or more guided acoustic wave modes of interest; receiving experimental data corresponding to a series of excitation pulses generated within the pipe at regular frequency increments; determining one or more frequencies of interest based on the experimental data; and selecting the specified frequency at which the at least one acoustic transducer is to transmit the excitation pulse for the pipe with the known properties. 10. The method of claim 1 , comprising determining, at the computing system, the measurement for the at least one parameter using at least one phase-velocity-based signal processing method or at least one amplitude-based signal processing method, or a combination thereof. 11. The method of claim 1 , wherein the C-SH acoustic wave mode is sensitive to a pressure within the wall of the pipe; and wherein calibrating the measurement using the C-SH acoustic wave mode comprises at least one of: compensating