Temperature-compensated strain-based transducer operating on differential measurements

The invention claimed is: 1. A pressure sensor assembly, comprising: a) a sensor housing having a first internal wall responsive to deform in response to a pressure difference between an interior and an exterior of the sensor housing; b) a fiber optic cable deployed through the sensor housing having a first section bonded to the first internal wall of the sensor housing such that the length of the first section changes both in response to deformation of the first internal wall from the pressure difference between the interior and exterior of the sensor housing and to changes in response to thermal deformation of the first internal wall; c) a second section of the fiber optic cable bonded to a second internal wall of the sensor housing that is not exposed to the pressure difference between the interior and exterior of the sensor housing such that the length of the second section changes only in response to thermal deformation of the second internal wall; d) a third section of the fiber optic cable not bonded to either of the first or second internal walls of the sensor housing; and e) wherein each of the first, second, and third sections of the fiber optic cable comprises at least one fiber Bragg grating. 2. The pressure sensor assembly of claim 1 wherein the first internal wall and the second internal wall are made of a material with the same or similar thermal expansion coefficient. 3. The pressure sensor assembly of claim 1 wherein the first internal wall and the second internal wall are made of the same material. 4. The pressure sensor assembly of claim 1 wherein the first internal wall responsive to deform to the pressure difference between the interior and exterior of the sensor housing is exposed to the outside pressure to be measured through an open port. 5. The pressure sensor assembly of claim 1 wherein the at least one fiber Bragg grating of first, second, and third sections of the fiber optic cable within the sensor housing are manufactured with a same laser exposure, at a same length, and have a same modulation depth profiles along a length of the at least one fiber Bragg grating. 6. The pressure sensor assembly of claim 1 wherein the third section of the fiber optic cable is bonded to a third internal wall of the sensor housing. 7. The pressure sensor assembly of claim 6 wherein the first internal wall and the second internal wall are made of a material with the same or similar coefficient of thermal expansion and the third internal wall is made of a material with a different coefficient of thermal expansion than the second internal wall. 8. The pressure sensor assembly of claim 1 , wherein a first pressure measurement and a first temperature measurement are made at the at least one fiber Bragg grating in the first section, wherein a second pressure measurement is made at the at least one fiber Bragg grating in the second section, and wherein a second temperature measurement at the at least one fiber Bragg grating in the third section. 9. The pressure sensor assembly of claim 8 , wherein a differential pressure measurement is determined based on a difference between the first pressure measurement and the second pressure measurement, wherein a differential temperature measurement is determined based on a difference between the first temperature measurement and the second temperature measurement, and wherein the differential pressure measurement is corrected based on the differential temperature measurement. 10. A method comprising: lowering a pressure sensor assembly into a wellbore, wherein the pressure sensor assembly comprises, a sensor housing having a first internal wall responsive to deform in response to a pressure difference between an interior and an exterior of the sensor housing; a fiber optic cable deployed through the sensor housing, wherein the fiber optic cable comprises, a first section having a first fiber Bragg grating and bonded to the first internal wall of the sensor housing such that the length of the first section changes both in response to deformation of the first internal wall from the pressure difference between the interior and exterior of the sensor housing and such that the length changes in response to thermal deformation of the first internal wall; a second section having a second fiber Bragg grating and bonded to a second internal wall of the sensor housing that is not exposed to the pressure difference between the interior and exterior of the sensor housing such that the length of the second section changes in response to thermal deformation of the second internal wall; and a third section having a third Bragg grating and not bonded to either of the first or second internal walls of the sensor housing; performing a differential pressure measurement in the wellbore around the pressure sensor assembly based difference in pressure measurements between the first fiber Bragg grating and the second fiber Bragg grating; and performing a differential temperature measurement in the wellbore around the pressure sensor assembly based a difference in temperature between the second fiber Bragg grating and the third fiber Bragg grating. 11. A method comprising: lowering pressure sensor assembly into a wellbore wherein the pressure sensor assembly comprises, a sensor housing having a first internal wall responsive to deform in response to a pressure difference between an interior and an exterior of the sensor housing; a fiber optic cable deployed through the sensor housing, wherein the fiber optic cable comprises, a first section having a first fiber Bragg grating and bonded to the first internal wall of the sensor housing such that the length of the first section changes both in response to deformation of the first internal wall from the pressure difference between the interior and exterior of the sensor housing and such that the length changes in response to thermal deformation of the first internal wall; a second section having a second fiber Bragg grating and bonded to a second internal wall of the sensor housing that is not exposed to the pressure difference between the interior and exterior of the sensor housing such that the length of the second section changes in response to thermal deformation of the second internal wall; and a third section having a third fiber Bragg grating and not bonded to either of the first or second internal walls of the sensor housing; performing a pressure measurement of a pressure obtained by the first fiber Bragg gratings; performing a first temperature measurement at the second Fiber Bragg grating; performing a second temperature measurement at the third Fiber Bragg grating; determining a differential temperature measurement between the first temperature measurement and the second temperature measurement; and correcting the pressure measurement based on the differential temperature measurement. 12. A distributed pressure monitoring system deployed across a hydrocarbon formation to be monitored comprising: a fiber optic cable to be positioned in a wellbore; multiple pressure sensor assemblies wherein each pressure sensor assembly comprises, a sensor housing having a first internal wall responsive to deform in response to a pressure difference between an interior and an exterior of the sensor housing, wherein the fiber optic cable is deployed through the sensor housing, and wherein within each sensor housing the fiber optic cable comprises, a first section having a first fiber Bragg grating and bonded to the first internal wall of the sensor housing such that the length of the first section changes both in response to deformation of the first internal wall from the pressure differ