Methods and apparatus for evaluating downhole conditions through RFID sensing

What is claimed is: 1. A method of making measurements in a well, comprising: associating a first communication assembly with the exterior of a casing string being placed in a borehole, wherein the first communication assembly is configured to communicate with radio frequency identification device (RFID) tags in the annulus surrounding the casing when the casing is in place within the borehole; wherein the first communication assembly includes a plurality of RFID sensor assemblies, with a first RFID sensor assembly configured to detect RFID tags in a first azimuthal area of the annulus, and a second RFID sensor assembly configured to detect tags in a second azimuthal region of the annulus, and wherein the first azimuthal region of the annulus is at least partially offset from the second azimuthal region of the annulus; pumping a first fluid into the annulus surrounding the casing, the fluid containing a first plurality of RFID tags; and interrogating the first plurality of RFID tags by the first communication assembly to determine the presence or absence of RFID tags within the first and second azimuthal regions of the annulus proximate the depth of the first communication assembly. 2. The method of claim 1 , wherein the first plurality of RFID tags in the first fluid are of a first configuration, and wherein the method further comprises pumping a second fluid into the annulus, the second fluid containing a second plurality of RFID tags of a second configuration. 3. The method of claim 1 , further comprising placing a plurality of communication assembles in longitudinally spaced relation along the casing string, in which a least a portion of such plurality of communication assemblies includes a plurality of RFID sensor assemblies, with a first RFID sensor assembly configured to detect RFID tags in a first azimuthal area of the annulus, and a second RFID sensor assembly configured to detect RFID tags in a second azimuthal region of the annulus, and wherein the first azimuthal region of the annulus is at least partially offset from the second azimuthal region of the annulus. 4. The method of claim 3 , wherein each RFID sensor assembly includes a pair of antennas, and wherein the method further comprises: transmitting an interrogation signal to the RFID tags from a first antenna of the pair of antennas; and receiving a response signal from the RFID tags through the second antenna of the pair of antennas. 5. The method of claim 3 , wherein each RFID sensor assembly includes a single antenna, and wherein the method further comprises: transmitting an interrogation signal to the RFID tags from the antenna; and receiving a response signal from the RFID tags through the antenna. 6. The method of claim 2 , wherein the second fluid comprises a sealant. 7. The method of claim 1 , wherein the communication assembly further comprises a plurality of acoustic sensors, each acoustic sensor oriented relative to a respective azimuthal region of the annulus. 8. A communication assembly, comprising: an assembly configured to form a portion of a casing string installed in an Earth borehole defined by formation sidewalls, wherein the casing string when placed in the borehole will define an annulus between the casing string and formation sidewalls, the assembly comprising, a plurality of RFID sensing assemblies, each RFID sensing assembly including at least one antenna configured to communicate with RFID tags in the annulus, and further including electronic control circuitry configured to communicate interrogation signals to RFID tags within the annulus and to receive signals from the RFID tags; a data storage device to receive information associated with signals received from the RFID tags; and a power source configured to supply electrical power to the electronic control circuitry and the data storage device; and wherein the antennas of each of at least a portion of the RFID sensing assemblies are configured and arranged around the circumference of the communication assembly such that each such RFID sensing assembly will be sensitive to RFID tags within an azimuthal region of the annulus, at least a portion of such azimuthal regions being at least partially offset from each another. 9. The communication assembly of claim 8 , wherein each RFID sensing assembly has a single antenna for both transmitting and receiving. 10. The communication assembly of claim 8 , wherein each RFID sensing assembly has a first antenna for transmitting interrogation signals to RFID tags and a second antenna for receiving signals from RFID tags. 11. The communication assembly of claim 8 , wherein the assembly is formed as a unit configured to be associated with the casing string. 12. The communication assembly of claim 8 , wherein the assembly is formed as an integral unit configured to threadably couple into the casing string. 13. The communication assembly of claim 8 , further comprising at least one temperature sensor configured to detect temperature fluid in the well annulus. 14. The communication assembly of claim 8 , further comprising a plurality of acoustic sensors, each sensor arranged to transmit acoustic energy into an azimuthal region of the well annulus, and to receive reflected energy. 15. The communication assembly of claim 8 , wherein the assembly comprises: a body member; and a plurality of ribs extending generally longitudinally along the body member, and in spaced relation to one another around the circumference of the body member; and wherein the electronic control circuitry of each of the RFID sensor assemblies is housed within one or more of the ribs. 16. The communication assembly of claim 15 , further comprising an additional sensor that is not an RFID sensing assembly, the additional sensor including control circuitry; and wherein at least a portion of the additional sensor control circuitry is housed within at least one of the ribs. 17. A system, comprising: a casing string having first and second communication assemblies supported by the casing string and disposed in longitudinally spaced relation to one another along the casing string, wherein each communication assembly is configured to obtain information associated with RFID tags in a plurality of radially offset regions of an annulus surrounding the casing when the casing is in place within a borehole; and a first plurality of RFID tags placed within a first fluid pumped into the annulus; and a control unit configured to receive data indicative of the information received from the first and second communication assemblies to provide information about the first fluid pumped into the annulus. 18. The system of claim 17 , further comprising a second fluid including second plurality of RFID tags, where the second plurality of RFID tags has a configuration different than that of the first plurality of RFID tags. 19. The system of claim 17 , wherein the obtained information associated with the RFID tags comprises the number of tags detected within an azimuthal region of the annulus within a selected time period. 20. The system of claim 17 , wherein each communication assembly further comprises a plurality of RFID sensor assemblies, each RFID sensor assembly arranged on the communication assembly to interrogate tags within a selected azimuthal region of the annulus. 21. The system of claim 17 , wherein each communication assembly further comprises a plurality of sensors selected from the group consisting essentially of acoustic sensors and temperature