Surface well testing systems and methods

The invention claimed is: 1. A well testing apparatus comprising: a separator configured to receive a multiphase fluid; a well control assembly coupled upstream of the separator so as to route the multiphase fluid from a well to the separator; and a fluid management assembly coupled downstream of the separator so as to receive separated fluids from the separator; wherein at least one of the well control assembly or the fluid management assembly includes: flow control equipment; a controller configured to control actuation of the flow control equipment so as to control flow of fluid in the well control assembly or the fluid management assembly; and a human-machine interface that enables an operator to monitor or control operation of the well control assembly or the fluid management assembly, wherein the human-machine interface is positioned with the flow control equipment so as to enable an operator to directly sense contextual clues about operation of the well control assembly or the fluid management assembly independent of the human-machine interface while using the human-machine interface; the fluid management assembly comprising: the controller and the flow control equipment mounted on a skid, the flow control equipment including at least one manifold mounted on the skid and coupled to receive at least one of the separated fluids from the separator, the at least one manifold includes valves for controlling flow of the at least one of the separated fluids through the at least one manifold, and the controller mounted on the skid controls actuation of the valves so as to control flow of the at least one of the separated fluids through the at least one manifold; multiple fluid tanks coupled to receive the at least one of the separated fluids via the at least one manifold; and wherein the controller mounted on the skid enables actuation of the valves so as to control flow of at least one of the following: to control flow of the at least one of the separated fluids from the separator to a selected fluid tank, to control flow of the at least one of the separated fluids from the selected fluid tank to another fluid tank, and to control flow of the at least one of the separated fluids from the fluid tanks to another destination. 2. The well testing apparatus of claim 1 , wherein the flow control equipment includes a gas manifold coupled to receive gas from the separator, a water manifold coupled to receive water from the separator, and an oil manifold coupled to receive oil from the separator; each of the gas, water, and oil manifolds includes valves for controlling flow of the gas, water, or oil through the respective manifolds; and the controller controls actuation of the valves of the gas, water, and oil manifolds so as to control flow of the gas, water, and oil through the respective manifolds. 3. The well testing apparatus of claim 2 , wherein each of the gas manifold, the water manifold, and the oil manifold are mounted along with the controller on a single, shared skid. 4. The well testing apparatus of claim 1 , wherein the human-machine interface is mounted on a skid along with the flow control equipment and the controller. 5. The well testing apparatus of claim 1 , wherein both the flow control equipment and the controller are positioned within a Zone 1 hazardous area. 6. The well testing apparatus of claim 1 , comprising a cabin having an additional human-machine interface that facilitates monitoring or control of the flow control equipment from the cabin. 7. The well testing apparatus of claim 1 , wherein both the flow control equipment and the controller are mounted on a skid, and wherein the human-machine interface includes a portable electronic device that is not mounted on the skid and that enables wireless remote monitoring or control of the flow control equipment by the operator via the portable electronic device. 8. A method of operating a well testing apparatus during a well test, the method comprising: routing a multiphase fluid to a separator of the well testing apparatus; separating the multiphase fluid into separate fluids via the separator; routing the separated fluids away from the separator; operating a control system to actuate flow control equipment of the well testing apparatus to control flow of the separated fluids downstream of the separator, wherein operating the control system includes sending an actuation signal from a control device of the control system to an actuator of a valve and opening or closing the valve via the actuator in response to the actuation signal; receiving user input to the control system via a human-machine interface, wherein sending the actuation signal from the control device of the control system is performed in response to the user input received via the human-machine interface, wherein the user input is indicative of a requested command to be performed by the control system; and using local intelligence at the control device to validate the requested command against one or more well testing apparatus constraints and then sending the actuation signal from the control device to the actuator of the valve after validating the requested command. 9. The method of claim 8 , wherein using local intelligence at the control device to validate the requested command against one or more well testing apparatus constraints includes using local intelligence at the control device to validate the requested command against one or more safety constraints of the well testing apparatus. 10. The method of claim 9 , wherein the requested command is to open the valve, the one or more safety constraints include a constraint that the valve not be open at the same time as a specific additional valve, and using local intelligence at the control device to validate the requested command against one or more safety constraints of the well testing apparatus includes using local intelligence to assess the operating status of the specific additional valve and to determine that the specific additional valve is closed before sending the actuation signal from the control device to the actuator of the valve to open the valve. 11. The method of claim 8 , wherein receiving user input to the control system via the human-machine interface includes receiving a user input that is indicative of a requested operational procedure for the control system, the requested operational procedure including actuating the valve and at least one additional action to be performed via the control system. 12. The method of claim 11 , comprising sending at least one additional actuation signal from the control device of the control system to at least one additional component of the control system, besides the valve, so as to control operation of the at least one additional component; wherein sending the actuation signal from the control device of the control system to the actuator of the valve and sending the at least one additional actuation signal from the control device of the control system to at least one additional component of the control system are performed in response to the requested operational procedure being requested through the user input received via the human-machine interface. 13. The method of claim 11 , wherein receiving the user input that is indicative of the requested operational procedure for the control system includes receiving a user input to route fluid from a source to a destination in the well testing apparatus. 14. The method of claim 13 , comprising automatically performing the requested operational procedure via the control device in response to the received user input, wherein automatically performing t