Methods and systems for in-line mixing of hydrocarbon liquids

What is claimed is: 1. A controller for an in-line mixing system for admixing liquids from a plurality of sets of tanks into a single pipeline, the controller comprising: a first input in signal communication with a first meter to measure a first flow rate of a first liquid, the first meter being positioned along a first mixing jumper, the first mixing jumper connected to a first tank and the single pipeline, the controller configured to obtain the first flow rate from the first meter via the first input as liquids are blended during a blending operation; a first output in signal communication with a first main valve, the first main valve positioned along a first main pipe, the first main pipe connected to the first tank and the single pipeline; a second input in signal communication with a second meter to measure a second flow rate of a second liquid, the second meter positioned along a second mixing jumper, the second mixing jumper connected to a second tank and the single pipeline, the controller also configured to obtain the second flow rate from the second meter via the second input as liquids are blended during the blending operation; a second output in signal communication with a second main valve, the first main valve positioned along a second main pipe, the second main pipe connected to the second tank and the single pipeline; and an input/output in signal communication with a first control valve and a second control valve, the first control valve configured to adjust flow of the first liquid via the first mixing jumper, thereby to modify the first flow rate, and the second control valve configured to adjust flow of the second liquid via the second mixing jumper, thereby to modify the second flow rate, the controller further configured to: as liquids are blended during the blending operation: close the first main valve and the second main valve, determine whether one or more of the first flow rate or the second flow rate is to be modified based on one or more of a target mix ratio, a ratio of the first flow rate and the second flow rate, the first flow rate, or the second flow rate, in response to a determination that the first flow rate is to be modified: adjust a position of the first control valve that adjusts flow through the first mixing jumper, thereby to modify the first flow rate, and in response to a determination that the second flow rate is to be modified: adjust a position of the second control valve that adjusts flow through the second mixing jumper, thereby to modify the second flow rate. 2. The controller of claim 1 , further comprising: a third input in signal communication with a third meter to measure a level of liquid of the first tank, and wherein the controller further is configured to obtain the level of liquid of the first tank from the third meter via the third input as liquids are blended during the blending operation; and a fourth input in signal communication with a fourth meter to measure a level of liquid of the second tank, and wherein the controller further is configured to obtain the level of liquid of the second tank from the fourth meter via the fourth input as liquids are blended during the blending operation. 3. The controller of claim 2 , wherein the level of liquid of the first tank and the level of liquid of the second tank are obtained by the controller continuously. 4. The controller of claim 2 , wherein the determination of whether one or more of the first flow rate or the second flow rate is to be modified includes the determination based on the level of liquid of the first tank and the level of liquid of the second tank. 5. The controller of claim 2 , wherein the level of liquid of the first tank and the level of liquid of the second tank are obtained by the controller intermittently. 6. The controller of claim 2 , wherein the determination of whether one or more of the first flow rate or the second flow rate is to be modified includes the determination based on at least one of the level of liquid of the first tank or the level of liquid of the second tank. 7. The controller of claim 6 , wherein the level of the liquid of the first tank affects the first flow rate, the level of the liquid of the second tank affects the second flow rate, and wherein the controller further is configured to adjust the first flow rate or the second flow rate, thereby to maintain the target mix ratio. 8. The controller of claim 1 , wherein the first liquid comprises a first hydrocarbon liquid, and the second liquid comprises a second hydrocarbon liquid. 9. The controller of claim 1 , wherein the determination of whether one or more of the first flow rate or the second flow rate is to be modified includes the determination based on comparison to a percentage of error. 10. The controller of claim 1 , further comprising a third input in signal communication with a third meter to measure a level of liquid of the first tank, wherein the controller further is configured to obtain the level of liquid of the first tank from the third meter via the third input as liquids are blended during the blending operation, and wherein the determination of whether one or more of the first flow rate or the second flow rate is to be modified includes the determination based on the level of liquid of the first tank. 11. The controller of claim 1 , further comprising a third input in signal communication with a third meter to measure a characteristic of a blend of the first liquid and the second liquid downstream of the first mixing jumper and the second mixing jumper, and wherein the controller further is configured to adjust the blending operation based on the characteristic of the blend. 12. The controller of claim 1 , further comprising a third input in signal communication with a computing device to receive one or more target blend parameters associated with the one or more of the target mix ratio, the ratio of the first flow rate and the second flow rate, the first flow rate, or the second flow rate, and wherein the controller further is configured to adjust the blending operation based on the one or more target blend parameters. 13. The controller of claim 12 , wherein the computing device comprises a user interface. 14. The controller of claim 1 , further comprising a third output in signal communication with a jumper isolation valve, the jumper isolation valve designed to close, thereby to isolate the first tank from the first mixing jumper, and wherein the controller further is configured to open the jumper isolation valve in response to initiation of the blending operation. 15. The controller of claim 1 , wherein the controller further is configured to open the first main valve in response to initiation of a single fluid operation from the first tank. 16. A controller for an in-line mixing system for admixing liquids from a plurality of sets of tanks into a single pipeline, the controller comprising: a first input in signal communication with a first meter to measure a first flow rate of a first hydrocarbon liquid, the first meter positioned along a first mixing jumper connected to a first tank and the single pipeline, the controller configured to obtain the first flow rate from the first meter via the first input as liquids are blended during a blending operation; a first output in signal communication with a first main valve, the first main valve positioned along a first main pipe connected to the first tank and the single pipeline; a second input in signal communication with a second meter to measure a second flow rate of a second hydrocarbon liquid, the second m