Method and device of MEMS process control monitoring and packaged MEMS with different cavity pressures

What is claimed is: 1. A method for fabricating an integrated MEMS (Micro Electro Mechanical System) device comprising: receiving a semiconductor substrate having a plurality of CMOS devices formed thereon, wherein the semiconductor substrate includes an upper surface, and wherein the upper surface of the semiconductor substrate is associated with an outgassing characteristic; forming a material layer on top of the semiconductor substrate, wherein the material layer includes a first lower cavity and a second lower cavity; forming a MEMS material layer comprising a first MEMS device on top of the first lower cavity and a second MEMS device on top of the second lower cavity; forming a capping structure comprising a plurality of caps including a first upper cap and a second upper cap, wherein forming the capping structure includes: receiving a capping structure, forming a dielectric layer above a surface of the capping substrate, and etching portions of the dielectric layer to expose portions of the surface of the capping substrate and to form the first upper cap and the second upper cap; coupling the capping structure to the MEMS material layer at a bonding interface, wherein the first upper cap and first lower cavity from a first MEMS cavity, wherein the first MEMS device is disposed therein, wherein the second upper cap and the second lower cavity form a second MEMS cavity, wherein the second MEMS device is disposed therein, wherein the first MEMS cavity is separate from the second MEMS cavity; and wherein the outgassing characteristic of the semiconductor substrate causes a gas pressure of the first MEMS cavity to be different from a gas pressure of the second MEMS cavity. 2. The method of claim 1 wherein an initial gas pressure of the first MEMS cavity and an initial gas pressure of the second MEMS cavity are substantially similar. 3. The method of claim 1 wherein a volume of the first MEMS cavity is different form a volume of the second MEMS cavity. 4. The method of claim 1 wherein the first MEMS device comprises a gyroscope; and wherein the second MEMS device comprises an accelerometer. 5. The method of claim 1 wherein a volume of the first lower cavity is substantially similar to a volume of the second lower cavity. 6. The method of claim 1 wherein a volume of the second upper cap is less than a volume of the first upper cap. 7. The method of claim 6 wherein a depth of the second upper cap is less than a depth of the first upper cap. 8. The method of claim 1 wherein the forming of the material layer on top of the semiconductor substrate comprises forming a dielectric layer above the upper surface of the semiconductor substrate; and etching portions of the dielectric layer to expose portions of the upper surface of the semiconductor substrate and to form the first lower cavity and the second lower cavity. 9. A method for fabricating an integrated MEMS (Micro Electro Mechanical System) device comprising: receiving a semiconductor substrate having a plurality of CMOS devices formed thereon, wherein the semiconductor substrate includes an upper surface, and wherein the upper surface of the semiconductor substrate is associated with an outgassing characteristic; forming a material layer on top of the semiconductor substrate, wherein the material layer includes a first lower cavity and a second lower cavity; forming a MEMS material layer comprising a first MEMS device on top of the first lower cavity and a second MEMS device on top of the second lower cavity; forming a capping structure comprising a plurality of caps including a first upper cap and a second upper cap, wherein the forming of the capping structure comprises: receiving a capping substrate, forming a dielectric layer above a surface of the capping substrate, and etching portions of the dielectric layer to expose portions of the surface of the capping substrate and to form the first upper cap, wherein the second upper cap is not exposed to portions of the surface of the capping structure, coupling the capping structure to the MEMS material layer at a bonding interface, wherein the first upper cap and first lower cavity from a first MEMS cavity, wherein the first MEMS device is disposed therein, wherein the second upper cap and the second lower cavity form a second MEMS cavity, wherein the second MEMS device is disposed therein, wherein the first MEMS cavity is separate from the second MEMS cavity; and wherein the outgassing characteristic of the semiconductor substrate causes a gas pressure of the first MEMS cavity to be different from a gas pressure of the second MEMS cavity.