System and approach for controlling a combustion chamber

What is claimed is: 1. A burner control mechanism comprising: a processor; a first mass flow sensor having a first port connectable to an air supply, a second port, and a signal terminal connected to the processor; and a second mass flow sensor having a first port connectable to the air supply, a second port, and a signal terminal connected to the processor; a first coupling point having a first port connected to the second port of the second mass flow sensor, a second port, and a third port; a second coupling point having a first port connected to the second port of the first mass flow sensor, a second port connected to the third port of the first coupling point, and a third port connectable to a combustion chamber; a shut-off valve having a first port connected to the second port of the first coupling point and a second port; an actuator connected to the shut-off device and having a terminal connected to the processor; a variable restriction device having a first port connected to the second port of the shut-off device and a second port; an actuator connected to the variable restriction device, and having a terminal connected to the processor; a shut-off valve having a first port connectable to a fuel supply and a second port connected to the second port of the variable restriction device; an actuator connected to the shut-off valve and having a terminal connected to the processor; a first connection having a restriction between the first port of the variable restriction device and a fourth port of the second coupling point; and a second connection having a restriction between the air supply and a fifth port of the second coupling point. 2. The mechanism of claim 1 , wherein: the shut-off valve is closed via a signal from the processor to the actuator of the shut-off valve; and data from the first and second mass flow sensors are taken and provided to the processor for storage and reference. 3. The mechanism of claim 2 , wherein: the shut-off valve is opened and fuel is provided to the second coupling point; feedback emissions signals from one or more sensors situated in or proximate to the combustion chamber are provided to the processor; and the variable restriction device is adjusted with a signal from the processor, based on data from the terminals of the first and second mass flow sensors provided for storage and reference and feedback emissions signals from the one or more sensors, to regulate fuel to the combustion chamber where the fuel is mixed with air for combustion to occur in the combustion chamber. 4. The mechanism of claim 2 , wherein: the shut-off valve is opened and the fuel supply is connected to the second coupling point; the processor derives a signal based on stored data from the first and second mass flow sensors, and the stored emissions data from one or more sensors situated in or proximate to the combustion chamber; and the signal is provided to the actuator of the variable restriction device for adjustment of the variable restriction device to affect the combustion to reduce emissions from the combustion chamber to a predetermined reference level. 5. The mechanism of claim 1 , wherein: the processor comprises a diagnostic component connected to the signal terminals of the first mass flow sensor and the second mass flow sensor; the processor comprises an indicator that determines whether a high pressure or low pressure exists according to signals from the signal terminals; the low pressure and high pressure are determined according to predetermined reference levels; and the diagnostic component can make automatic corrections for detected errors. 6. A burner control mechanism comprising: a processor; a first mass flow sensor having a first port connectable to an air supply, a second port, and a signal terminal connected to the processor; and a second mass flow sensor having a first port connectable to the air supply, a second port, and a signal terminal connected to the processor; a first coupling point having a first port connected to the second port of the second mass flow sensor, a second port, and a third port; a second coupling point having a first port connected to the second port of the first mass flow sensor, a second port connected to the third port of the first coupling point, and a third port connectable to a combustion chamber; a shut-off valve having a first port connected to the second port of the first coupling point and a second port; an actuator connected to the shut-off device and having a terminal connected to the processor; a variable restriction device having a first port connected to the second port of the shut-off device and a second port; an actuator connected to the variable restriction device, and having a terminal connected to the processor; a shut-off valve having a first port connectable to a fuel supply and a second port connected to the second port of the variable restriction device; an actuator connected to the shut-off valve and having a terminal connected to the processor; and wherein: the processor comprises a diagnostic component connected to the signal terminals of the first mass flow sensor and the second mass flow sensor; the processor comprises an indicator that determines whether a high pressure or low pressure exists according to signals from the signal terminals; the low pressure and high pressure are determined according to predetermined reference levels; and the diagnostic component can make automatic corrections for detected errors. 7. The mechanism of claim 6 , further comprising: a first connection having a restriction between the first port of the variable restriction device and a fourth port of the second coupling point; and a second connection having a restriction between the air supply and a fifth port of the second coupling point. 8. The mechanism of claim 7 , wherein: the shut-off valve is closed via a signal from the processor to the actuator of the shut-off valve; and data from the first and second mass flow sensors are taken and provided to the processor for storage and reference. 9. The mechanism of claim 8 , wherein: the shut-off valve is opened and fuel is provided to the second coupling point; feedback emissions signals from one or more sensors situated in or proximate to the combustion chamber are provided to the processor; and the variable restriction device is adjusted with a signal from the processor, based on data from the terminals of the first and second mass flow sensors provided for storage and reference and feedback emissions signals from the one or more sensors, to regulate fuel to the combustion chamber where the fuel is mixed with air for combustion to occur in the combustion chamber. 10. The mechanism of claim 8 , wherein: the shut-off valve is opened and the fuel supply is connected to the second coupling point; the processor derives a signal based on stored data from the first and second mass flow sensors, and the stored emissions data from one or more sensors situated in or proximate to the combustion chamber; and the signal is provided to the actuator of the variable restriction device for adjustment of the variable restriction device to affect the combustion to reduce emissions from the combustion chamber to a predetermined reference level.