Method and apparatus for hardware configured network

What is claimed is: 1. A transceiver for a hardware configured optical network, the transceiver comprising: a) a first optical port that receives an input optical signal from the hardware configured network, the input optical signal comprising client data traffic on a receive optical carrier and receive control information for configuring an optical network element encoded as a modulation on the receive optical carrier having a frequency that is less than a modulation frequency of the client data traffic; b) a receiver having an input that is optically coupled to the first optical port, the receiver comprising a photodiode that directly detects the input optical signal, the receiver decoding the receive control information for configuring the optical network element and receiving the client data traffic; c) a tunable laser that generates an optical signal at an output, the optical signal having an optical carrier with a wavelength; d) a modulator having an input that is optically coupled to the output of the tunable laser, the modulator imparting modulation directly onto the optical signal with the frequency that is less than the modulation frequency of a transmit client data traffic, the modulator thereby generating a first transmit optical control signal that represents transmit control information having the wavelength of the optical carrier and the modulator generating a second transmit optical control signal that configures an element in the hardware configured optical network, wherein the configuration of the element in the hardware configured network comprises automatic provisioning of a tunable channel and establishment of a data connection; and e) a second optical port that transmits the first transmit optical control signal representing the transmit control information to the hardware configured optical network. 2. The transceiver for the hardware configured optical network of claim 1 wherein the first and second transmit optical control signal are different transmit optical control signals. 3. The transceiver for the hardware configured optical network of claim 1 wherein the modulator further comprises an electrical modulation input that receives the transmit control information. 4. The transceiver for the hardware configured optical network of claim 1 wherein the modulator is configured to impart the transmit client data traffic on the optical signal. 5. The transceiver for the hardware configured optical network of claim 1 further comprising a second modulator having an input that is optically coupled to the output of the tunable laser and an output coupled to the input of the modulator, wherein the second modulator is configured to impart the transmit client data traffic on the optical signal. 6. The transceiver for the hardware configured optical network of claim 1 wherein the tunable laser is configured to generate a wavelength in a wavelength range from 1528 nm to 1567 nm. 7. The transceiver for the hardware configured optical network of claim 1 wherein the tunable laser is configured to generate a wavelength that determines a destination of the transmit optical control signal in the hardware configured optical network. 8. The transceiver for the hardware configured optical network of claim 1 wherein the tunable laser is configured to generate a wavelength that determines a path of at least one of the first and second transmit optical control signal in the hardware configured optical network. 9. The transceiver for the hardware configured optical network of claim 1 wherein at least one of the first and second transmit optical control signal comprises a multi-point communication protocol. 10. The transceiver for the hardware configured optical network of claim 1 wherein at least one of the first and second transmit optical control signal comprises a collision avoidance protocol. 11. The transceiver for the hardware configured optical network of claim 10 wherein the collision avoidance protocol comprises an Ethernet protocol. 12. The transceiver for the hardware configured optical network of claim 1 wherein the second transmit optical control signal that configures the element in the hardware configured optical network performs a turn-up operation of the element. 13. The transceiver for the hardware configured optical network of claim 1 wherein the second transmit optical control signal that configures the element in the hardware configured optical network performs a tuning of the element. 14. The transceiver for the hardware configured optical network of claim 1 wherein second transmit optical control signal that configures the element in the hardware configured optical network performs a programming operation of the element. 15. The transceiver for the hardware configured optical network of claim 1 wherein the transceiver is configured as a small form factor optical transceiver. 16. The transceiver for the hardware configured optical network of claim 15 wherein the small form factor optical transceiver comprises a SFP transceiver. 17. A method for automatically establishing a data connection in a hardware configured network, the method comprising: a) connecting a first transceiver that is tunable to an optical link in the hardware configured network; b) connecting a second transceiver to the optical link in the hardware configured network; c) generating at the first transceiver a transmit optical signal comprising client data traffic at a wavelength; d) encoding at the first transceiver a modulation representing control information by imparting a modulation onto the generated transmit optical signal comprising client data traffic at the wavelength having a modulation frequency that is less than a modulation frequency of the client data traffic, thereby generating a transmit optical control signal that represents the control information; e) transmitting the transmit optical control signal that represents the control information over the optical link and receiving the transmit optical control signal at the second transceiver; f) decoding at the second transceiver the control information encoded in the received transmit optical control signal using electrical filtering to remove the client data traffic from the received transmit optical control signal; g) configuring the second transceiver using the decoded control information and establishing the data connection between the first transceiver and the second transceiver over the optical link based on the configuration of the second transceiver; and h) tuning the wavelength generated by the first transceiver to determine a path in the hardware configured network. 18. The method for automatically establishing the data connection of claim 17 further comprising transmitting the transmit optical control signal that represents the control information through a wavelength selective switch. 19. The method for automatically establishing the data connection of claim 17 further comprising transmitting the transmit optical control signal that represents the control information through an optical amplifier. 20. The method for automatically establishing the data connection of claim 17 further comprising transmitting the transmit optical control signal that represents the control information through a programmable filter. 21. A method for automatically establishing a data connection in a hardware configured network, the method comprising: a) connecting a first transceiver to an optical link in the hardware configured network; b)