HVAC system relay autotuning and verification

What is claimed is: 1. A method for autotuning a heating, ventilation and air conditioning (HVAC) system controller coupled to a controlled system, the method comprising: receiving a performance coefficient; providing a step-input to the controlled system using an autotuner relay to measure an ultimate gain and an ultimate period of the controlled system, the autotuner relay taking control from the HVAC system controller and providing a periodic step function to the controlled system to determine limits of the controlled system, the ultimate gain and the ultimate period determined from a limit cycle of the controlled system; adjusting the ultimate gain and the ultimate period to account for a relay hysteresis; applying a tuning rule to determine a proportional gain and an integral time from the ultimate gain and the ultimate period; updating the HVAC system controller with the proportional gain and integral time; and verifying the proportional gain and integral time, comprising: setting a performance envelope at least partially determined by the performance coefficient; applying a step-input to provoke a closed-loop response; and comparing the closed loop response with the performance envelope to determine whether the closed-loop response is within the performance envelope. 2. The method of claim 1 , further comprising comparing adjusting the proportional gain and integral time by adjusting the tuning rule by comparison to internal model control (IMC) based results. 3. The method of claim 1 , further comprising controlling a fan coil unit with the HVAC system controller. 4. The method of claim 3 , wherein controlling the fan coil unit comprises controlling a heating/cooling medium flow rate though a coil of the fan coil unit, a speed of a fan of the fan coil unit, or a combination thereof. 5. The method of claim 1 , wherein adjusting the ultimate gain and the ultimate period includes determining an adjustment factor for the ultimate period and the ultimate gain by: modeling the controlled system as a first order plus dead time system; and averaging an adjustment factor of a range of ratios of time delay versus time constants of the controlled system. 6. The method of claim 5 , wherein the range of time delay to time constant ratio is between about 0.1 and about 0.5. 7. The method of claim 1 , wherein setting the performance envelope comprises determining: a maximum overshoot as a function of the performance coefficient; a first time point that is larger than an apparent time delay of the HVAC system; a second time point that is equal to an apparent time delay plus a peak time of the HVAC system and is greater than the first time point; a third time point that is a time constant of an exponential term that bounds sluggishness of the closed-loop response moving to a steady state; a fourth time point that is a time constant of an exponential term that bounds how fast the closed-loop response moves to steady state; and a fifth time point that is a response monitoring time termination for the exponential terms. 8. The method of claim 7 , wherein: the maximum overshoot is about 0.5 minus about 0.35 times the performance coefficient; the first time point is 1.5 times the time delay; the second time point is about 4.6 times the time delay; the fourth time point is about 5 times the time delay minus about 3.5 times the performance coefficient times the time delay; and the fifth time point is the lesser of the time delay plus three times the third time and the time delay plus three times the fourth time. 9. The method of claim 7 , further comprising estimating the delay time as about 0.3 times the ultimate period. 10. The method of claim 7 , wherein determining the fourth time includes estimating a ratio of a natural frequency divided by an ultimate frequency over a range of the ratios of the time delay divided by the time constant across at least three tuning cases. 11. A heating, ventilation and air conditioning (HVAC) system, comprising: a fan coil unit including a fan and a coil; a duct extending between the fan coil unit and a volume of air contained in a zone; a sensor disposed in or proximal to the volume of air and configured to sense an air temperature of a zone; and a controller coupled to the fan coil unit and the sensor, the controller being configured to receive a signal from the sensor and provide a signal to the fan coil unit so as to regulate at least one of supply air temperature, heating/cooling medium flowrate, wherein the controller includes an input device that is selectable to provide a performance coefficient to the controller such that when the controller is autotuned, a result of the autotuning is compared against a performance envelope determined at least partially by the performance coefficient; an autotuner relay providing a step-input to the controlled system to measure an ultimate gain and an ultimate period of the controlled system, the autotuner relay taking control from the controller and providing a periodic step function to the controlled system to determine limits of the controlled system, the ultimate gain and the ultimate period determined from a limit cycle of the controlled system. 12. The HVAC system of claim 11 wherein the controller includes a proportional-integral (PI) controller and the HVAC system further comprises a control feedback loop including the PI controller, a controlled system including the fan coil unit and the sensor, and the autotuner relay disposed in parallel to the PI controller. 13. The HVAC system of claim 12 , wherein the input device is configured to set the performance coefficient α of between about 0 and about 1, wherein the controller sets the performance envelope with a maximum overshoot Mp of 0.5-0.35a, wherein: M p = e - ζπ ⁢ / ⁢ 1 - ζ 2 . 14. The HVAC system of claim 13 , wherein the controller sets the performance envelope using a plurality of time points, the plurality of time points including: a first time point that is larger than an apparent time delay of the HVAC system; a second time point that is equal to an apparent time delay plus a peak time of the HVAC system; a third time point that is a time constant of an exponential term that bounds sluggishness of the closed-loop response moving to a steady state; a fourth time point that is a time constant of an exponential term that bounds how fast the closed-loop response moves to steady state; and a fifth time point that is a response monitoring time termination for the exponential terms. 15. The HVAC system of claim 14 , wherein: the first time point is 1.5 times the time delay; the second time point is about 4.6 times the time delay; the fourth time point is about 5 times the time delay minus about 3.5 times the performance coefficient times the time delay; and the fifth time point is the lesse