Integrated circuit and method for processing synchronized network frames using a hardware synchronization circuit

What is claimed is: 1. An integrated circuit (IC) device, the IC device comprising: an Ethernet frame processor; at least one Ethernet port coupled to the Ethernet frame processor; and a hardware synchronization circuit coupled to the Ethernet frame processor and to the at least one Ethernet port, the hardware synchronization circuit comprising: a controller; a local clock coupled to the controller; a media-independent peripheral coupled to the controller; and a media-dependent peripheral coupled to the media-independent peripheral; wherein power can be provided to the hardware synchronization circuit independent of the Ethernet frame processor; wherein the hardware synchronization circuit is configured to process messages according to the IEEE 802.1 AS standard to perform IEEE 802.1AS functions in hardware while the Ethernet frame processor is powered down, the IEEE 802.1AS functions performed in hardware comprising frame timestamping and at least one of residence time calculation, propagation delay calculation, rate ratio calculation, and neighbor rate ratio calculation; wherein the controller is configured to forward a frame to at least one of a microcontroller coupled to the IC device and the Ethernet frame processor when the frame includes an IEEE 802.1AS function that the hardware synchronization circuit cannot process. 2. The IC device of claim 1 , wherein a double-type integer used in IEEE 802.1AS functions is stored in a 64-bit register within the hardware synchronization circuit with the first 4 bits allocated to an integer value and the trailing 60 bits allocated to a fractional value. 3. The IC device of claim 1 , wherein timestamp values are stored within the hardware synchronization circuit using std_logic_vectors. 4. The IC device of claim 1 , wherein rate ratio is calculated using a non-restoring division algorithm implemented via iterative subtraction and shifting using registers in the hardware synchronization circuit. 5. The IC device of claim 1 , wherein residence time and propagation delay are calculated using subtraction and shift registers in the hardware synchronization circuit. 6. The IC device of claim 1 , wherein a local synchronization clock is configured using separate adders and subtractors to detect and compute seconds and nanoseconds separately. 7. The IC device of claim 1 , wherein the hardware synchronization circuit is configured to process a partial range of header data in an Ethernet frame and store the data in registers in the hardware synchronization circuit. 8. The IC device of claim 1 , wherein the media-dependent peripheral is coupled to a single port. 9. A method for processing synchronized network frames, the method comprising: powering up a hardware synchronization circuit; receiving an IEEE 802.1AS frame; determining if the IEEE 802.1AS frame requires processing by a microcontroller; powering up the microcontroller, processing the IEEE 802.1AS frame using the microcontroller when the IEEE 802.1AS frame requires processing by a microcontroller, and powering down the microcontroller; and processing the IEEE 802.1AS frame using a hardware synchronization circuit when the IEEE 802.1AS frame does not require processing by a microcontroller, wherein processing the IEEE 802.1AS frame using a hardware synchronization circuit comprises performing an IEEE 802.1AS function in hardware while an Ethernet frame processor is powered down, the IEEE 802.1AS function performed in hardware comprising frame timestamping and at least one of residence time calculation, propagation delay calculation, rate ratio calculation, and neighbor rate ratio calculation; wherein the hardware synchronization circuit is configured to forward a frame to at least one of the microcontroller and the Ethernet frame processor when the frame includes an IEEE 802.1AS function that the hardware synchronization circuit cannot process. 10. The method of claim 9 , wherein a double-type integer used in processing the IEEE 802.1AS frame is stored in a 64-bit register in the hardware synchronization circuit with the first 4 bits allocated to an integer value and the trailing 60 bits allocated to a fractional value. 11. The method of claim 9 , wherein timestamp values are stored within the hardware synchronization circuit using std_logic_vectors. 12. The method of claim 9 , wherein rate ratio is calculated using a non-restoring division algorithm implemented via iterative subtraction and shifting using registers in the hardware synchronization circuit. 13. The method of claim 9 , wherein residence time and propagation delay are calculated using subtraction and shift registers in the hardware synchronization circuit. 14. The method of claim 9 , wherein a local synchronization clock is configured using separate adders and subtractors to detect and compute seconds and nanoseconds separately. 15. The method of claim 9 , wherein the hardware synchronization circuit is configured to process a partial range of header data in an Ethernet frame and store the data in registers in the hardware synchronization circuit. 16. An automobile Ethernet network, the network comprising: at least one switch, the switch configured with a hardware synchronization circuit and coupled to a switch microcontroller; at least one end node, the end node coupled to the switch, to an end node microcontroller, and to a transceiver within which a hardware synchronization circuit is configured; and a time-sensitive Ethernet device coupled to the end node microcontroller; wherein the network is synchronized using IEEE 802.1AS; and wherein IEEE 802.1AS functions are performed by the hardware synchronization circuit in the switch and by the hardware synchronization circuit in the transceiver within the end node that are configured to process messages according to the IEEE 802.1 AS standard in hardware while the switch microcontroller and end node microcontroller remain powered off, wherein the IEEE 802.1AS functions performed in hardware by the hardware synchronization circuits while the switch microcontroller and the end node microcontroller remain powered off comprise frame timestamping and at least one of residence time calculation, propagation delay calculation, rate ratio calculation, and neighbor rate ratio calculation, wherein the hardware synchronization circuit in the transceiver within the end node includes a controller configured to forward a frame to at least one of the end node microcontroller and an Ethernet frame processor of the end node when the frame includes an IEEE 802.1AS function that the hardware synchronization circuit cannot process. 17. The automobile Ethernet network of claim 16 , wherein resynchronization of the powered off switch microcontroller can be facilitated by the hardware synchronization circuit in the at least one switch and resynchronization of the powered off end node microcontroller can be facilitated by the hardware synchronization circuit in the at least one end node.