Temperature delta control for a hydronic heating/cooling system

What is claimed is: 1. A heating and/or cooling system comprising: at least one controller assembly controlling the system, the at least one controller assembly including: a movement actuator configured to connect to a valve in order to control water flow through a hydronic emitter; a temperature sensor interface configured to interface to first and second temperature sensors, wherein the first temperature sensor and the second temperature sensor measure an inlet temperature and an outlet temperature, respectively, of the hydronic emitter and wherein a measured temperature delta is a difference between the inlet and outlet temperatures; a thermostat interface configured to obtain a temperature setpoint and a room temperature for an environmental entity; and a computer device comprising: a processor; a first memory device; and a second memory device storing computer-readable instructions that, when executed by the processor, cause the at least one controller assembly to perform: obtaining, through the thermostat interface, the temperature setpoint and the room temperature; accessing a target temperature delta from a first data structure stored on the first memory device, wherein the first data structure maps the target temperature delta based on the temperature setpoint and the room temperature and wherein the first data structure maps the target temperature delta to a temperature difference between the temperature setpoint and the room temperature; mapping, in a second data structure stored in the first memory device, a resulting position of the valve to the temperature difference when the measured temperature delta equals the target temperature delta; when a mapping for the temperature difference is stored in the second data structure, instructing the movement actuator to directly adjust the valve to the resulting position; when the mapping for the temperature difference is not stored in the second data structure, incrementally controlling the movement actuator to adjust the valve so that water flow through the hydronic emitter corresponds to an incremental change of the measured temperature delta; waiting for the measured temperature delta to satisfy a stability condition; and repeating the incrementally controlling and the waiting until the measured temperature delta equals the target temperature delta; controlling the movement actuator to adjust the valve so that water flow through the hydronic emitter results in the measured temperature delta equaling the target temperature delta; and repeating the obtaining, the accessing, and the controlling for an updated room temperature. 2. The heating and/or cooling system of claim 1 further comprising a first and a second controller assembly, wherein: the first controller assembly controls water flow through a first emitter and comprises a first processor and a third memory device storing computer-readable instructions that, when executed by the first processor, cause the first controller assembly to perform: accessing a first target temperature delta for the first emitter from first data provided by a first thermostat; and wherein: the second controller assembly controls water flow through a second emitter and comprises a second processor and a fourth memory device storing computer-readable instructions that, when executed by the second processor, cause the second controller assembly to perform: accessing a second target temperature delta for the second emitter from second data provided by a second thermostat. 3. A method for controlling a fluid flowing through a first emitter of a heating and/or cooling system, the method comprising: obtaining, through a thermostat interface, a first temperature setpoint and a first room temperature for a first environmental entity; accessing a first target temperature delta based on a temperature difference between the first temperature setpoint and the first room temperature; measuring a first measured temperature delta between a first inlet and a first outlet of a first emitter, wherein the first measured temperature delta is a difference between the first inlet and outlet temperatures; mapping a resulting position of a first valve to the temperature difference when the first measured temperature delta equals the first target temperature delta; when a mapping for the temperature difference and the resulting position is stored in a data structure, instructing a first movement actuator to directly adjust the first valve to the resulting position; when the mapping for the temperature difference and the resulting position is not stored in the data structure, incrementally controlling the first movement actuator to adjust the first valve so that fluid flow through the first emitter corresponds to an incremental change of the first measured temperature delta; waiting for the first measured temperature delta to satisfy a stability condition; and repeating the incrementally controlling and the waiting until the first measured temperature delta equals the first target temperature delta; adjusting, through a first movement actuator, the first valve so that fluid flow through the first emitter results in the first measured temperature delta equaling the first target temperature delta; and repeating the obtaining, the accessing, the measuring, and the adjusting for an updated first room temperature. 4. The method of claim 3 further comprising: obtaining, through the thermostat interface, a second temperature setpoint and a second room temperature for a second environmental entity; accessing a second target temperature delta based on the second temperature setpoint and the second room temperature; measuring a second measured temperature delta between a second inlet and a second outlet of a second emitter, wherein the second measured temperature delta is a difference between the second inlet and outlet temperatures; and adjusting, through a second movement actuator, a second valve so that fluid flow through the second emitter corresponds to the second measured temperature delta equaling the second target temperature delta. 5. The method of claim 3 , wherein the fluid comprises water. 6. The method of claim 3 further comprising: when a difference between the first temperature setpoint and the first room temperature is greater than a first predetermined amount, setting the first target temperature delta so that the first valve is fully open to obtain a maximum power level from the first emitter. 7. The method of claim 6 further comprising, further comprising: when the difference between the first temperature setpoint and the first room temperature is less than the first predetermined amount and greater than a second predetermined amount, setting the first target temperature delta so that the first valve is partially open to obtain a partial power level from the first emitter. 8. The method of claim 7 further comprising: when the difference between the first temperature setpoint and the first room temperature is less than a third predetermined amount, fully closing the first valve so that fluid flow is stopped. 9. The method of claim 8 , wherein the third predetermined amount corresponds to the first room temperature exceeding the first temperature setpoint by 0.2 degrees C. 10. The method of claim 5 , wherein a heating source of the heating and/or cooling system is a boiler. 11. A non-transitory computer-readable medium storing computer-executable instructions that, when executed by a processor, cause an apparatus to perform: obtaining a temperature setpoint and a room temperature for an environmental entity; accessing a target temperature delta based on a