Ultrasonic flow meter auto-tuning for reciprocal operation of the meter

What is claimed is: 1. A method for performing auto-tuning in an ultrasonic flowmeter including a first circuit associated with a first transducer of the ultrasonic flowmeter and a second circuit associated with a second transducer of the ultrasonic flowmeter for reciprocal operation, the method comprising: using a controller of the ultrasonic flowmeter to cause an upstream signal and a downstream signal to be exchanged between the between the first and second transducers, the upstream signal being transmitted from the first transducer to the second transducer and the downstream signal being transmitted from the second transducer to the first transducer; using the controller to compare at least one of a group comprising respective maximum amplitudes of the upstream signal and the downstream signal and respective center frequencies of a Fast Fourier Transform (FFT) of the upstream signal and the downstream signal; and responsive to the controller determining, based on the comparison, that at least one of the group comprising the respective maximum amplitudes and the respective center frequencies do not match, using the controller to adjust an impedance value in at least one of the first circuit or the second circuit so that the center frequency of an FFT of the upstream signal and the center frequency of an FFT of the downstream signal substantially match after the adjustment. 2. The method of claim 1 , wherein using the controller to adjust the impedance value comprises: setting a first component of the impedance at a first value of a first range of values and a second component of the impedance at a first value of a second range of values; determining a value of a respective data point by exchanging the upstream and downstream signals between the first transducer and the second transducer and determining an absolute value of a difference in maximum amplitude of the upstream signal and the downstream signal; incrementing the second component to a next value in the second range and determining the value of the respective data point, wherein incrementing the second component and determining the respective data point is continued until a local minimum in the data points is determined; setting the second component to a value corresponding to the local minimum; incrementing the first component to a next value in the first range and determining the value of the respective data point, wherein incrementing the first component and determining the respective data point is continued until a global minimum in the data points is determined; and setting the first component to a value corresponding to the global minimum. 3. The method as recited in claim 2 , wherein: the local minimum is determined when the second component has been set to all values in the second range or the value of the respective data point is no longer becoming smaller than a previous value; and the global minimum is determined when the first component has been set to all values in the first range or the value of the respective data point is no longer becoming smaller than a previous value. 4. The method as recited in claim 3 , wherein the first component is a resistance and the second component is a capacitance. 5. The method as recited in claim 2 , wherein determining the value of the respective data point further comprises determining an absolute value of a difference in the center frequency of the FFT of the upstream signal and the center frequency of the FFT of the downstream signal. 6. The method as recited in claim 1 , wherein, as a result of adjusting the impedance value of at least one of the first circuit or the second circuit so that the center frequency of an FFT of the upstream signal and the center frequency of an FFT of the downstream signal substantially match, an impedance value of the first circuit and an impedance value of the second circuit substantially match. 7. An integrated circuit (IC) device comprising: a microcontroller that includes an interface configured to connect to a first transducer and a second transducer; memory operably connected to the microcontroller and containing instructions that, when executed by the microcontroller, cause the microcontroller to: control an exchange of an upstream signal and a downstream signal between the first and second transducers in which the upstream signal is transmitted by the first transducer and received by the second transducer and the downstream signal is transmitted by the second transducer and received by the first transducer; compare at least one of a group comprising respective maximum amplitudes of the upstream signal and the downstream signal and respective center frequencies of a Fast Fourier Transform (FFT) of the upstream signal and the downstream signal; and responsive to determining, based on the comparison, that at least one of the group comprising the respective maximum amplitudes and the respective center frequencies do not match, adjust an impedance value in at least one of a first circuit associated with the first transducer or a second circuit associated with the second transducer so that the center frequency of an FFT of the upstream signal and the center frequency of an FFT of the downstream signal substantially match after the adjustment. 8. The IC device of claim 7 , wherein adjustment of the impedance value comprises using the microcontroller to: set a first component of the impedance at a first value of a first range of values and a second component of the impedance at a first value of a second range of values; determine a value of a respective data point by exchanging the upstream and downstream signals between the first transducer and the second transducer and determining an absolute value of a difference in maximum amplitude of the upstream signal and the downstream signal; increment the second component to a next value in the second range and determine the value of the respective data point, wherein incrementing the second component and determining the respective data point is continued until a local minimum in the data points is determined; set the second component to a value corresponding to the local minimum; increment the first component to a next value in the first range and determine the value of the respective data point, wherein incrementing the first component and determining the respective data point is continued until a global minimum in the data points is determined; and setting the first component to a value corresponding to the global minimum. 9. The IC device of claim 8 , wherein: the local minimum is determined when the second component has been set to all values in the second range or the value of the respective data point is no longer becoming smaller than a previous value; and the global minimum is determined when the first component has been set to all values in the first range or the value of the respective data point is no longer becoming smaller than a previous value. 10. The IC device of claim 9 , wherein the first component is a resistance and the second component is a capacitance. 11. The IC device of claim 8 , wherein determining the value of the respective data point further comprises determining an absolute value of a difference in the center frequency of the FFT of the upstream signal and the center frequency of the FFT of the downstream signal. 12. A flow meter system comprising: first and second transducers spaced apart from one another; a first circuit associated with the first transducer; a second circuit associated with the second transducer; a microcontroller operably connected to the first and second transducers; and memory operably connected to the microco