Adaptive backoff time in power-over-ethernet detection cycles

What is claimed is: 1. A power sourcing equipment controller for providing power using power-over-Ethernet (PoE), the power sourcing equipment controller comprising: a voltage-output logic block to output a sequence of voltage signals, wherein the voltage signals comprise at least a detection signal and a classification signal; a current-measurement logic block to measure current provided responsive to the voltage signals; a backoff-time-determination logic block to determine a backoff time in response to the current-measurement logic block detecting the provided current exceeding a predetermined threshold, wherein the backoff time is determined based on an amount of time needed for discharging an internal capacitor associated with the powered device; and a timing logic block to cause the voltage-output logic block to delay the output of a next sequence of voltage signals based on the determined backoff time, thereby facilitating powering up of a device compliant with a different PoE standard. 2. The power sourcing equipment controller of claim 1 , wherein the device being powered up is a legacy type 1 device compliant with IEEE 802.3af standard, and wherein the power sourcing equipment controller is compliant with IEEE 802.3bt standard. 3. The power sourcing equipment controller of claim 1 , wherein the backoff-time-determination logic block is to compute the amount of time needed for discharging the internal capacitor based on a charging duration of the internal capacitor and a maximum allowed value of the internal capacitor. 4. The power sourcing equipment controller of claim 3 , wherein the internal capacitor is charged by current responsive to the classification signal, and wherein the voltage-output logic block is to reduce a duration for outputting the classification signal in response to the current-measurement logic block detecting the provided current exceeding the predetermined threshold. 5. The power sourcing equipment controller of claim 3 , wherein the backoff-time-determination logic block is to determine the backoff time by: obtaining an adaptive backoff time by adding a buffer to the computed amount of time needed for discharging the internal capacitor; and comparing the adaptive backoff time with a default backoff time. 6. The power sourcing equipment controller of claim 1 , wherein the backoff-time-determination logic block is to compute the amount of time needed for discharging the internal capacitor based on a number of current spikes observed by the current-measurement logic block and a maximum allowed value of the internal capacitor. 7. The power sourcing equipment controller of claim 1 , further comprising a host interface to communicate with a host controller, wherein the host interface is to send an error message to the host controller in response to the current-measurement logic block detecting that current responsive to the detection signal is outside of a predetermined range. 8. The power sourcing equipment controller of claim 7 , wherein the host interface comprises an Inter-Integrated Circuit (I 2 C) interface. 9. The power sourcing equipment controller of claim 7 , wherein the host interface is to receive, from the host controller, a backoff time used to delay the voltage-output logic block to output the next sequence of voltage signals. 10. The power sourcing equipment controller of claim 1 , wherein the backoff-time-determination logic block is to increment the determined backoff time in response to the current-measurement logic block detecting that current responsive to the detection signal in the next sequence of voltage signals is outside of a predetermined range. 11. A method for providing power from a power sourcing equipment controller using power-over-Ethernet (PoE), the method comprising: outputting, by the power sourcing equipment controller, a sequence of voltage signals, wherein the voltage signals comprise at least a detection signal and a classification signal; measuring current provided responsive to the voltage signals; determining a backoff time in response to detecting the provided current exceeding a predetermined threshold, wherein determining the backoff time comprises computing an amount of time needed for discharging an internal capacitor associated with the powered device; and delaying a next sequence of voltage signals based on the determined backoff time, thereby facilitating powering up a device compliant with a different PoE standard. 12. The method of claim 11 , wherein the device being powered up is a legacy type 1 device compliant with IEEE 802.3af standard, and wherein the power sourcing equipment controller is compliant with IEEE 802.3bt standard. 13. The method of claim 11 , wherein the amount of time needed for discharging the internal capacitor is computed based on a charging duration of the internal capacitor and a maximum allowed value of the internal capacitor. 14. The method of claim 13 , wherein the internal capacitor is charged by current responsive to the classification signal; and wherein the method further comprises reducing a duration for outputting the classification signal in response to the current-measurement logic block detecting that the provided current exceeding the predetermined threshold. 15. The method of claim 13 , wherein determining the backoff time comprises: obtaining an adaptive backoff time by adding a buffer to the computed amount of time needed for discharging the internal capacitor; and comparing the adaptive backoff time with a default backoff time. 16. The method of claim 11 , wherein the amount of time needed for discharging the internal capacitor is computed based on a number of current spikes observed by the current-measurement logic block and a maximum allowed value of the internal capacitor. 17. The method of claim 11 , further comprising: sending, by a host interface to a host controller, an error message, in response to detecting that current responsive to the detection signal is outside of a predetermined range. 18. The method of claim 17 , wherein the host interface comprises an Inter-Integrated Circuit (I 2 C) interface. 19. The method of claim 17 , further comprising receiving, from the host controller via the host interface, a backoff time used to delay the voltage-output output logic block to output the next sequence of voltage signals. 20. The method of claim 11 , further comprising: incrementing the determined backoff time in response to detecting that current responsive to the detection signal in the next sequence of voltage signals is outside of a predetermined range.