Self-calibrated method of determining borehole fluid acoustic properties

What is claimed is: 1. A method of determining an acoustic parameter of a downhole fluid using an acoustic assembly comprising a plurality of acoustic reflectors each having at least one acoustically reflective surface at least partially immersed in the downhole fluid, the method comprising: transmitting a plurality of pulses; measuring values for at least one wave property measured for reflections of the plurality of pulses received at at least one acoustic receiver, including: a first value for a first reflection traveling a first known distance from a first acoustically reflective surface having a first known acoustic impedance, wherein the first known distance is a distance from the first acoustically reflective surface to the at least one acoustic receiver during the measuring; a second value for a second reflection traveling a second known distance substantially the same as the first known distance from a second acoustically reflective surface having a second known acoustic impedance substantially different than the first known acoustic impedance, wherein the second known distance is a distance from the second acoustically reflective surface to the at least one acoustic receiver during the measuring; and a third value for a third reflection traveling a third known distance substantially different from each of the first known distance and the second known distance from a third acoustically reflective surface having a third known acoustic impedance substantially the same as the second known acoustic impedance, wherein the third known distance is a distance from the third acoustically reflective surface to the at least one acoustic receiver during the measuring; and estimating the acoustic parameter using the values; wherein the plurality of pulses and the reflections are each transmitted through the downhole fluid, wherein the at least one acoustic receiver is configured to rotate about an axis of the acoustic assembly, and wherein the first acoustically reflective surface, the second acoustically reflective surface, and the third acoustically reflective surface are azimuthally distributed about the axis, such that each of the first reflection, the second reflection, and the third reflection each return to the at least one acoustic receiver from a different azimuth with respect to the axis. 2. An apparatus for determining an acoustic parameter of a downhole fluid in a borehole, the apparatus comprising: a tool having disposed thereon an acoustic assembly, the acoustic assembly comprising at least one transducer and a plurality of acoustic reflectors having acoustically reflective surfaces; wherein the tool is configured to at least partially immerse the at least one transducer and the acoustically reflective surfaces, and wherein the acoustic assembly is configured to i) transmit a plurality of pulses through the downhole fluid, and ii) measure values for at least one wave property for reflections of the plurality of pulses, including: a first value for a first reflection traveling a first known distance from a first acoustically reflective surface having a first known acoustic impedance; a second value for a second reflection traveling a second known distance substantially the same as the first known distance from a second acoustically reflective surface having a second known acoustic impedance substantially different than the first known acoustic impedance; and a third value for a third reflection traveling a third known distance substantially different from each of the first known distance and the second known distance from a third acoustically reflective surface having a third known acoustic impedance substantially the same as the second known acoustic impedance; and a processor configured to estimate the acoustic parameter using the values, wherein the at least one transducer is configured to rotate about an axis of the acoustic assembly, and wherein the first acoustically reflective surface, the second acoustically reflective surface, and the third acoustically reflective surface are azimuthally distributed about the axis, such that each of the first reflection, the second reflection, and the third reflection each return to the acoustic assembly from a different azimuth with respect to the axis.