Active noise control in a helmet

What is claimed is: 1. A noise reducing system comprising: a helmet; a first loudspeaker (FL spkr ) disposed in the helmet at an opposing position from a second loudspeaker (FR spkr ); a first microphone (FL Mic ) disposed in a vicinity of the first loudspeaker (FL spkr ) and a second microphone (FR Mic ) disposed in a vicinity of the second loudspeaker (FR spkr ); and an active noise controller including a processor and being operably coupled to the first loudspeaker (FL spkr ), the second loudspeaker (FR spkr ), the first microphone (FL Mic ), and the second microphone (FR Mic ) to perform active noise control; wherein a first magnitude frequency response is defined as being a product of a magnitude response of the first loudspeaker (FL spkr ) and a magnitude response of the first microphone (FL Mic ); wherein a second magnitude frequency response is defined as being a product of the magnitude response of the first loudspeaker (FL spkr ) and a magnitude response of the second microphone (FR Mic ); wherein the second magnitude frequency response is subtracted from the first magnitude frequency response to provide a third magnitude frequency response; wherein a fourth magnitude frequency response is defined as being a product of a magnitude response of the second loudspeaker (FR spkr ) and the magnitude response of the second microphone (FR Mic ); wherein a fifth magnitude frequency response is defined as being a product of the magnitude response of the second loudspeaker (FR spkr ) and the magnitude response of the first microphone (FL Mic ); wherein the fifth magnitude frequency response is subtracted from the fourth magnitude response to provide a sixth magnitude frequency response, and wherein the third magnitude frequency response at least partially overlaps with the sixth magnitude response when the active noise controller is activated. 2. The system of claim 1 , wherein the helmet comprises a shell and an isolation layer; wherein the isolation layer is disposed in the shell and has a first receptable and a second receptable at opposing positions; and the first loudspeaker (FL spkr ) is disposed in the first receptable and the second loudspeaker (FR spkr ) is disposed in the second receptable. 3. The system of claim 2 , wherein the shell has a front opening; and the first microphone (FL mic ) is disposed between the front opening and the first loudspeaker (FL spkr ); and the second microphone (FR mic ) is disposed between the front opening and the second loudspeaker (FR spkr ). 4. The system of claim 1 , wherein the active noise control controller is of a combined feed-forward and feedback type. 5. The system of claim 1 , wherein the helmet includes an isolation layer having memory foam. 6. The system claim 5 , wherein the isolation layer includes a deflating vacuum cushion. 7. The system of claim 5 , wherein the isolation layer includes an inflatable splint. 8. The system of claim 1 , wherein the first microphone (FL mic ) and the second microphone (FR mic ) are disposed inside the helmet at a same curved plane as the first loudspeaker (FL spkr ) and the second loudspeaker (FR spkr ), respectively, such that first microphone (FL mic ) and the second microphone (FR mic ) are arranged to face a front side opening of the helmet in a direction where a noise source resides. 9. A noise reducing method comprising: acoustically reproducing two electrical noise reducing signals at two opposing positions in a helmet with a first loudspeaker (FL spkr ) and a second loudspeaker (FR spkr ); and picking up sound at positions in a vicinity of where the noise reducing signals are reproduced with a first microphone (FL Mic ) and a second microphone (FR Mic ); wherein the first microphone (FL Mic ) and the second microphone (FR Mic ) are disposed inside the helmet such that the first microphone (FL Mic ) and the second microphone (FR Mic ) are arranged to face an opening of the helmet, wherein a first magnitude frequency response is defined as being a product of a magnitude response of the first loudspeaker (FL spkr ) and a magnitude response of the first microphone (FL Mic ); wherein a second magnitude frequency response is defined as being a product of the magnitude response of the first loudspeaker (FL spkr ) and a magnitude response of the second microphone (FR Mic ); wherein the second magnitude frequency response is subtracted from the first magnitude frequency response to provide a third magnitude frequency response; wherein a fourth magnitude frequency response is defined as being a product of a magnitude response of the second loudspeaker (FR spkr ) and the magnitude response of the second microphone (FR Mic ); wherein a fifth magnitude frequency response is defined as being a product of the magnitude response of the second loudspeaker (FR spkr ) and the magnitude response of the first microphone (FL Mic ); wherein the fifth magnitude frequency response is subtracted from the fourth magnitude response to provide a sixth magnitude frequency response, and wherein the third magnitude frequency response at least partially overlaps with the sixth magnitude response when the operation of acoustically reproducing two electrical noise reducing signals is activated. 10. The method of claim 9 , wherein generating the two electrical noise reducing signals employs a two-channel combined feed-forward and feedback type active noise reduction algorithm. 11. The method of claim 9 , wherein the first microphone (FL mic ) and the second microphone (FR mic ) are disposed inside the helmet at a same curved plane as the first loudspeaker (FL spkr ) and the second loudspeaker (FR mic ), respectively, such that first microphone (FL mic ) and the second microphone (FR mic ) are arranged to face a front side opening of the helmet in a direction where a noise source resides. 12. A noise reducing system comprising: a helmet; a first loudspeaker (FL spkr ) and a second loudspeaker (FR spkr ), each of the first loudspeaker (FL spkr ) and the second loudspeaker (FR spkr ) are positioned in the helmet at opposing positions from one another; a first microphone (FL Mic ) disposed in a vicinity of the first loudspeaker (FL spkr ); a second microphone (FR Mic ) disposed in a vicinity of the second loudspeaker (FR spkr ); and an active noise controller including a processor and two channels each with an error-signal input, a reference-signal input and an output; wherein a first magnitude frequency response is defined as being a product of a magnitude response of the first loudspeaker (FL spkr ) and a magnitude response of the first microphone (FL Mic ); wherein a second magnitude frequency response is defined as being a product of the magnitude response of the first loudspeaker (FL spkr ) and a magnitude response of the second microphone (FR Mic ); wherein the second magnitude frequency response is subtracted from the first magnitude frequency response to provide a third magnitude frequency response; wherein a fourth magnitude frequency response is defined as being a product of a magnitude response of the second loudspeaker (FR spkr ) and the magnitude response of the second microphone (FR Mic ); wherein a fifth magnitude frequency response is defined as being a product of the magnitude response of the second loudspeaker (FR spkr ) and the magnitude response of the first microphone (FL mic ); wherein the fifth magnitude frequency response is subtracted from the fourth magnitude response to provide a sixth magnitude frequency response, and wherein the third magnitude frequency response at least partially overlaps with the sixth magnitude response when the active noise contro