Bluetooth low energy based emergency backup and recovery solution in an industrial controller

What is claimed: 1. A method comprising: when a main power source is off, outputting electric energy from storage within a backup power source; storing information in a shared memory that is written by a processor, wherein the shared memory is configured to be accessed by the processor and a BLUETOOTH low energy (BLE) module and to operate using at least some of the electric energy output from the backup power source when the main power source is off; switching the BLE module to a power save mode in response to detecting a communication problem with the processor via a wire connection between the BLE module and the processor; switching the BLE module out of a power save mode in response to the BLE module receiving a communication from an external device; reading, by the BLE module, the information stored in the shared memory, wherein the BLE module is coupled to the backup power source, and wherein the BLE module is configured to operate using at least some of the electric energy output from the backup power source when the main power source is off; and transmitting, by the BLE module, the information to an external device through a wireless communication channel using a BLUETOOTH communication protocol. 2. The method of claim 1 , further comprising: providing electric energy to the shared memory and to BLE module through an automatic switch by: when the main power source is on, receiving electric energy from the main power source; and when the main power source is off, switching to receive electric energy from the backup power source. 3. The method of claim 1 , further comprising: switching the BLE module to a power save mode when a voltage output from the main power source is below a threshold value. 4. The method of claim 1 , further comprising: transmitting the information to the external device through the wireless communication channel after switching out of the power save mode. 5. The method of claim 1 , further comprising: receiving configuration information through the BLE module, the configuration information transmitted to the BLE module from an external device through another wireless communication channel using the BLUETOOTH communication protocol. 6. An apparatus comprising: a backup power source configured to store electric energy and to output electric energy when a main power source is off; a shared memory configured to be accessed by a processor and a BLUETOOTH low energy (BLE) module, to store information written by the processor, and to operate using at least some of the electric energy output from the backup power source when the main power source is off; switching the BLE module to a power save mode in response to detecting a communication problem with the processor via a wire connection between the BLE module and the processor; switching the BLE module out of a power save mode in response to the BLE module receiving a communication from an external device; and the BLE module coupled to the backup power source, the BLE module configured to operate using at least some of the electric energy output from the backup power source when the main power source is off, to read the information stored in the shared memory, and to transmit the information to an external device through a wireless communication channel using a BLUETOOTH communication protocol. 7. The apparatus of claim 6 , further comprising an automatic switch configured to: when the main power source is on, receive electric energy from the main power source; when the main power source is off, switch to receive electric energy from the backup power source; and provide the received electric energy to the shared memory and to the BLE module. 8. The apparatus of claim 6 , wherein the BLE module is further configured to: switch to a power save mode when a voltage output from the main power source is below a threshold value. 9. The apparatus of claim 6 , wherein the BLE module is further configured to: transmit the information to the external device through the wireless communication channel after switching out of the power save mode. 10. The apparatus of claim 6 , wherein the backup power source includes a super capacitor. 11. The apparatus of claim 6 , wherein the backup power source includes a rechargeable backup power source, and wherein the rechargeable backup power source is configured to receive electric energy from the main power source when the main power source is on. 12. The apparatus of claim 6 , the processor further configured to: receive configuration information through the BLE module, the configuration information transmitted to the BLE module from an external device through another wireless communication channel using the BLUETOOTH communication protocol. 13. A system comprising: an industrial controller configured to control an industrial process in an industrial facility, the industrial controller comprising a processor configured to operate when a main power source is on; and a BLUETOOTH low energy (BLE) based emergency backup and recovery tool coupled to the industrial controller, the tool comprising: a backup power source configured to store electric energy and to output electric energy when the main power source is off; a shared memory configured to be accessed by the processor and a BLE module, to store information written by the processor, and to operate using at least some of the electric energy output from the backup power source when the main power source is off; switch to a power save mode in response to detecting a communication problem with the processor via a wire connection between BLE module and the processor; switch out of a power save mode in response to receiving a communication from the external device; and the BLE module coupled to the backup power source, the BLE module configured to operate using at least some of the electric energy output from the backup power source when the main power source is off, to read the information stored in the shared memory, and to transmit the information to an external device through a wireless communication channel using a BLUETOOTH communication protocol. 14. The system of claim 13 , wherein the tool further comprises an automatic switch configured to: when the main power source is on, receive electric energy from the main power source; when the main power source is off, switch to receive electric energy from the backup power source; and provide the received electric energy to the shared memory and to BLE module. 15. The system of claim 13 , wherein the BLE module is further configured to: switch to a power save mode when a voltage output from the main power source is below a threshold value. 16. The system of claim 13 , wherein the BLE module is further configured to: transmit the information to the external device through the wireless communication channel after switching out of the power save mode. 17. The system of claim 13 , wherein the processor is further configured to: receive configuration information through the BLE module, the configuration information transmitted to the BLE module from an external device through another wireless communication channel using the BLUETOOTH communication protocol.