Systems and methods for correcting downstream power excursions during upstream loading operations in optical networks

What is claimed is: 1. A network element, comprising: a processor; a first line port optically coupled to a first optical fiber link carrying a first optical signal having a first plurality of passbands; a flexible ROADM module including a wavelength selective switch in optical communication with the first line port, a multiplexer, and one or more control block, and being operable to selectively multiplex the first optical signal into a second optical signal having a second plurality of passbands, the one or more control block operable to control the wavelength selective switch and the multiplexer; a second line port optically coupled to a second optical fiber link and operable to carry the second optical signal having the second plurality of passbands, the second line port in optical communication with the wavelength selective switch; and a memory comprising a non-transitory processor-readable medium storing an orchestrator application having one or more service component, and storing processor-executable instructions that when executed by the processor cause the processor to: responsive to receiving a first signal indicative of an impending network state change, pause all power adjustments by the control block on the flexible ROADM module and save at least one power set point value for each active passband from the first optical signal multiplexed into the second optical signal, the network state change being responsive to service activation or service deactivation affecting the first optical signal; responsive to receiving a second signal indicative of the network state change, adjust an optical power of each active passband from the first optical signal multiplexed into the second optical signal using the power set point values. 2. The network element of claim 1 , wherein the one or more service component is an orchestration control protocol, and wherein the orchestration control protocol, in communication with the orchestration application, determines the at least one power set point value for each active passband from the first optical signal multiplexed into the second optical signal and saves the at least one power set point value for each active passband in the memory. 3. The network element of claim 1 , wherein adjusting the optical power of each active passband from the first optical signal multiplexed into the second optical signal using the power set point values is defined further as providing instructions to the wavelength selective switch to cause the wavelength selective switch to selectively attenuate wavelengths of light within at least one active passband. 4. The network element of claim 1 , wherein adjusting the optical power of each active passband from the first optical signal multiplexed into the second optical signal using the power set point values is defined further as providing instructions to the wavelength selective switch to cause the wavelength selective switch to selectively amplify wavelengths of light within at least one active passband. 5. The network element of claim 1 , wherein adjusting the optical power of each active passband from the first optical signal multiplexed into the second optical signal using the power set point values is defined further as adjusting the power level of each passband independently of other passbands. 6. The network element of claim 1 , wherein adjusting the optical power of each active passband from the first optical signal multiplexed into the second optical signal using the power set point values is defined further as dynamically adjusting the power level of passbands based on real-time network conditions. 7. The network element of claim 1 , wherein the degree further comprises an optical power monitor configured to measure the power level of individual passbands and provide feedback to the processor for adjusting the power levels. 8. The network element of claim 1 , wherein after the optical power of each active passband from the first optical signal multiplexed into the second optical signal is adjusted using the power set point values, the processor executable instructions cause the processor to determine if a delta power threshold value relative to the power set point values for each active passband from the first optical signal multiplexed into the second optical signal has been exceeded; and if the delta power threshold value relative to the power set point values for each active passband from the first optical signal multiplexed into the second optical signal has not been exceeded, the processor executable instructions cause the processor to generate and transmit a third signal via the first line port, the third signal indicating the optical power adjustment of each active passband from the first optical signal multiplexed into the second optical signal was successful; or if the delta power threshold value relative to the power set point values for each active passband from the first optical signal multiplexed into the second optical signal has been exceeded, the processor executable instructions cause the processor to generate and transmit a fourth signal via the first line port, the fourth signal indicating the optical power adjustment of each active passband from the first optical signal multiplexed into the second optical signal was not successful. 9. A network element, comprising: a first flexible ROADM module comprising: a first system port; a second system port; a first line port optically coupled to a first optical fiber link carrying a first optical signal having a first group of passbands; a first processor; and a first memory comprising a non-transitory processor-readable medium storing a first orchestrator application having one or more first service component, and storing first processor-executable instructions; a second flexible ROADM module comprising: a third system port; a fourth system port; a second line port optically coupled to the first line port of the first flexible ROADM module; a second processor; and a second memory comprising a non-transitory processor-readable medium storing a second orchestrator application having one or more second service component, and storing second processor-executable instructions; a third flexible ROADM module comprising: a fifth system port; a sixth system port; a third line port optically coupled to the first line port of the first flexible ROADM module; a third processor; and a third memory comprising a non-transitory processor-readable medium storing a third orchestrator application having one or more third service component, and storing third processor executable instructions; wherein the second processor-executable instructions, when executed by the second processor, cause the second processor to: responsive to receiving a first signal indicative of an impending network state change, pause all power adjustments by a second control block on the second flexible ROADM module and save at least one first power set point value for each active passband from the first group of passbands from the first flexible ROADM module, the network state change being responsive to service activation or service deactivation affecting the first optical signal; and responsive to receiving a second signal indicative of the network state change, adjust an optical power of each active passband from the first optical signal using the first power set point values; and wherein the third processor-executable instructions, when executed by the third processor cause the third processor to: responsive to receiving the first signal indicative of the impending network state change, pause all power adjustments by a third control block on the third flexible ROADM module and save at least one second power s