Method of manufacturing a pressure sensor

The invention claimed is: 1. A method of manufacturing an overheat or fire alarm detection system, comprising the steps of: micromachining a pressure sensor, and securing a sensor tube in fluid communication with said pressure sensor; wherein said micromachining step comprises: forming one or more layers including a first layer, doping at least a portion of a first layer to form a doped portion; to form an electrical terminal, forming a cavity at least partially within said doped portion; and forming a deformable diaphragm over said cavity, wherein said micromachining step comprises forming a recess in an upper surface of said diaphragm, said upper surface facing away from said first layer and being at least partially aligned with said cavity, and wherein said micromachining step comprises forming at least two recesses having different depths. 2. The method of claim 1 , wherein said sensor tube comprises a hollow tube containing a material that evolves gas upon heating. 3. The method of claim 1 , wherein said micromachining step comprises: forming a plurality of doped portions; forming a cavity partially within each doped portion; and forming a plurality of recesses in said upper surface, each recess being at least partially aligned with a cavity. 4. The method of claim 1 , wherein said step of forming one or more layers comprises forming a flexible, electrically conductive layer between said deformable diaphragm and said first layer. 5. A pneumatic pressure sensor comprising: a first layer having a plurality of cavities in a first surface; and a deformable diaphragm having: a first surface facing and covering said cavities, and a second surface facing away from said first layer and having a plurality of recesses, wherein each recess is at least partially aligned with one of said cavities and at least a first recess has a greater depth than a second recess; wherein said first layer comprises a semiconductor wafer having a plurality of doped portions and one or more of said cavities is at least partially within one of said doped portions; and wherein each doped portion provides an electrical terminal that is closable by the movement of a portion of said diaphragm into one of the plurality of cavities. 6. The pneumatic pressure sensor of claim 5 , wherein said first layer and said diaphragm each have a thickness of 100 μm or less. 7. A method of manufacturing the pneumatic pressure sensor of claim 5 , comprising the steps of: micromachining a first layer having a plurality of cavities in a first surface; and micromachining a deformable diaphragm that covers said cavities and has a plurality of recesses of different depths in a second surface of said diaphragm that faces away from said first layer.