WO2021173218A1 - Systems, devices, and methods for drag-reduction - Google Patents

Abstract

A fluid-drag reduction system that can be configured to (i) mount to a vehicle, and (ii) transition between a first configuration and a second configuration independent of a door system and can include a fairing system. The fairing system can include a fairing that can be configured to transition between a first position in the first configuration of the fluid-drag reduction system and a second position in the second configuration of the fluid-drag reduction system.

Description

SYSTEMS, DEVICES, AND METHODS FOR DRAG-REDUCTION

CROSS-REFERENCE TO RELATED APPLICATIONS

[0001] This application claims priority to United States Provisional Application No. 62/983,669 filed February 29, 2020 and to United States Provisional Application No. 63/076,929 filed September 10, 2020, the contents of which are incorporated herein by reference in their entirety as if set forth verbatim.

FIELD OF THE TECHNOLOGY

[0002] The present disclosure relates to systems and methods of vehicle attachments.

BACKGROUND

[0003] Aspects of the present application relates to the field of vehicle attachments. More particularly, it relates to an apparatus used to reduce fluid-drag when a vehicle, for example, an autonomous vehicle, operator-assisted vehicle, or operator-driven vehicle) is in motion. In the vehicle attachment field, there have been many different types of apparatuses designed to reduce fluid-drag. Some of these apparatuses involve stationary panels, or foldable panels that extend beyond the rear of the vehicle.

[0004] Related art fluid-drag reduction apparatuses are designed to attach to a hinged-double door systems and their panels extend only a few feet beyond the rear of the vehicle, thereby sub-optimally reducing the drag induced by turbulent fluid behind the vehicle, and as a result, the panels of these related art apparatuses are not readily operable on vehicles having door systems other than the hinged-double door system.

[0005] As it will be appreciated, installing and maintaining a different drag-reduction apparatus for each vehicle door system is undesirable. Operators will have to learn different operation protocols for each different drag-reduction apparatus, and maintenance teams will require more unique parts in inventory which can be costly to maintain.

[0006] Other related art fluid-drag reduction apparatuses do not autonomously retract or extend their panels and require at least some operator intervention, thereby requiring manual retraction and/or extension of the panels which can be prone to operators either forgetting to extend the apparatuses resulting in sub-optimal fleet fuel economy, or forgetting to retract the apparatuses leading to safety hazards, for example, in adverse weather conditions where extended panels increase the surface area of the vehicle and can cause it to slide or rollover on a road in high-crosswind and/or slick road conditions. Should the operator remember to retract the apparatus, the manual retracting process can also be a safety hazard for operators as it can put them in danger by having to stop and leave the vehicle, for example, in a thunderstorm or blizzard.

[0007] It will also be appreciated that forgetting to retract the apparatus upon entering the destination location can cause damage to the vehicles, buildings, or the apparatus itself, if the operator is not aware that the apparatus is not retracted. It will also be appreciated that forgetting to extend the apparatus upon leaving the departure location can reduce the fuel- efficiency of the vehicle, resulting in greater operating costs for the owners and/or operators of the vehicle.

[0008] Aspects of the present disclosure address these and other disadvantages.

SUMMARY

[0009] Disclosed examples provide systems and methods for a fluid-drag reduction system. Consistent with the disclosed examples, a system is disclosed. In an example, a fluid-drag reduction system that can be configured to (i) mount to a vehicle, and (ii) transition between a first configuration and a second configuration independent of a door system and can include a fairing system. The fairing system can include a fairing that can be configured to transition between a first position in the first configuration of the fluid-drag reduction system and a second position in the second configuration of the fluid-drag reduction system.

[0010] In examples, the first configuration of the autonomous fluid-drag reduction can be a fully retracted configuration.

[0011] In examples, the second configuration of the fluid-drag reduction system can be a fully deployed configuration.

[0012] In examples, the fluid-drag reduction system can include a third configuration between the first and second configurations.

[0013] In examples, the fluid-drag reduction system can include an attachment system that can be configured to transition the fluid-drag reduction system between the first configuration and the second configuration. The attachment system can include an actuator that can be configured to rotate a first gear in a first or second direction, thereby transitioning the fluid- drag reduction system between the first and second configurations. A cord that can be configured to (i) rotate a second gear based on a rotation of the first gear, and (ii) attach to a cord at a connection point causing movement of the cord based on a rotation of the first gear thereby causing the fluid-drag reduction system to transition between the first and second configurations. The attachment system can include a network of pulleys that can be configured to attach to the vehicle and that can be configured to receive a cord.

[0014] In examples, fluid-drag reduction system can include a guide rail that can be configured to (i) attach to a side of the vehicle and (ii) can mount thereon, the fairing.

[0015] In examples, the cord can be a first cord and the connection point can be a first connection point, and the attachment system can include the cord that can be configured to (i) rotate a third gear and (ii) attach to a second cord at a second connection point causing the second cord to move based on a rotation of the first gear thereby causing the fluid-drag reduction system to transition between the first and second configurations.

[0016] In examples, the attachment system that can be configured to transition the fluid-drag reduction system between the first configuration and the second configuration. The attachment system can include a network of pulleys that can be configured to attach to the vehicle and can be configured to receive a cord comprising chain and cable. The cord can be in communication with the network of pulleys, a cord retaining device, and the fairing. The cord can be operable to communicate one or more rotations of the cord retaining device to the fairing system thereby transitioning the fluid-drag reduction system between the first configuration and the second configuration. An actuator can be configured to rotate the cord retaining device, the cord retaining device can be configured to retain the cord thereon.

[0017] In examples, the fluid-drag reduction system can include a mounting system that can include a guide rail that can be configured to (i) attach to a side of the vehicle and (ii) mount thereon, the fairing.

[0018] In examples, the fairing can be a first fairing.

[0019] In examples, the fairing system can include a second fairing that can be configured to transition between the first position in the first configuration of the fluid-drag reduction system and the second position in the second configuration of the fluid-drag reduction system.

[0020] In examples, the network of pulleys can be a first network of pulleys.

[0021] In examples, the cord can be a first cord.

[0022] In examples, the actuator can be a first actuator.

[0023] In examples, the cord retaining device can be a first cord retaining device. [0024] In examples, the attachment system can include a second network of pulleys that can be configured to attach to the vehicle and that can be configured to receive a second cord including cord and cord. The second cord can be in communication with the second network of pulleys, a second cord retaining device, and the second fairing. The second cord can be operable to communicate one or more rotations of the second cord retaining device to the fairing system thereby transitioning the fluid-drag reduction system between the first configuration and the second configuration. A second actuator can be configured to rotate the second cord retaining device, the second cord retaining device can be configured to retain the second cord thereon.

[0025] In examples, the guide rail can be a first guide rail.

[0026] In examples, the side of the vehicle can be a first side of the vehicle.

[0027] In examples, the mounting system can include a second guide rail that can be in communication with the second cord and the second fairing. The second guide rail can be configured to (i) attach to a second side of the vehicle and (ii) mount thereon, the second fairing.

[0028] In examples, the fluid-drag reduction system can include a controls system that can include a microcontroller which can be in communication with a sensor and an actuator. The microcontroller can be configured to send or receive one or more of: sensor data or instructions to cause actuation of the actuator. The sensor can be configured to send or receive at least one of: data indicative of the fluid-drag reduction system being in the first configuration, position data, or data indicative of electrical current powering on a portion of a vehicle’s electrical system or powering off a portion of a vehicle’s electrical system. The actuator can be configured to send or receive at least one of: instructions to deactivate the actuator or instructions to activate the actuator.

[0029] In examples, the sensor can be a position sensor that can be configured to transmit data indicative of the fluid-drag reduction system being in the first configuration to the microcontroller.

[0030] In examples, the sensor can be a position sensor that can be configured to transmit data indicative of the fluid-drag reduction system being in the second configuration to the microcontroller.

[0031] In examples, the sensor can be a relay that can be configured to transmit data indicative of at least one of: a turn signal or a reverse light being in either an on-state or an off- state to the microcontroller. [0032] In examples, the sensor can be a Global Positioning System (GPS) transceiver that can be configured to transmit position data to the microcontroller.

[0033] In examples, the sensor can be a non-vehicular sensor comprising one or more of: a radar, a camera, an IR camera, or an ultrasonic proximity sensor, and that can be configured to transmit data to the microcontroller.

[0034] In examples, the actuator can be a stepper motor that can be configured to receive instructions to either activate or deactivate and transmit indexing data to the microcontroller.

[0035] In examples, the fairing can transition between the first and second positions along an arcuate path.

[0036] In examples, the arcuate path can include a radius of curvature defined by a tension member.

[0037] In examples, the tension member can include a fixed length defining the radius of curvature for the arcuate path, a first end pivotably attached to the fairing, and a second end pivotably attached to the vehicle, thereby causing the fairing to transition along the arcuate path.

[0038] In examples, the faring can include a panel, the panel of the fairing can be constructed of a foam-aluminum composite including: a first aluminum sheet, a second aluminum sheet, and polyethylene foam disposed therebetween.

[0039] In examples, the fluid-drag reduction system is an autonomous fluid-drag reduction system.

[0040] In examples, the fluid-drag reduction system is a semi-autonomous fluid-drag reduction system.

[0041] Consistent with the disclosed examples, a method is disclosed. In an example, the method can include receiving, from a GPS transceiver, position data associated with a current location and a timestamp associated with the position data, and determining, using one or more processors, a speed based on the position data, the timestamp, previous position data, and previous timestamp. Additionally the method can include, determining, using the one or more processors, whether the speed is greater than a user-configurable threshold, and in response to determining that the speed is greater than the user-configurable threshold, transmitting, to an actuator, a signal indicating the actuator to deploy a fluid-drag reduction system. [0042] In examples, the method can include receiving, from a position sensor, a signal indicating the fluid-drag reduction system is in a fully deployed configuration, and transmitting, to the actuator, a signal that indicates the actuator to halt deployment of the fluid- drag reduction system.

[0043] In examples, the method can include receiving, from a position sensor, a signal indicating the fluid-drag reduction system is in a fully retracted configuration, and transmitting, to the actuator, a signal that indicates the actuator to halt retraction of the fluid-drag reduction system.

[0044] In examples, the method can include receiving, over a network, a user-configurable threshold.

[0045] In examples, the method can include streaming, over a network, a map navigation data comprising at least one of: a compass heading, map data comprising transit data, a destination location, a departure location, or traffic data.

[0046] In examples, the method can include determining that the speed is not greater than the user-configurable threshold transmitting, to an actuator, a signal indicating the actuator to retract the fluid-drag reduction system.

[0047] In examples, the method can include determining that the speed is not greater than the user-configurable threshold determining that the vehicle’s hazard lights are activated, and transmitting, to an actuator, a signal indicating the actuator to retract the fluid-drag reduction system.

[0048] In examples, the method can include, in response to determining that the speed is not greater than the user-configurable threshold determining that the current position is within a predetermined radius of a destination location, and transmitting, to an actuator, a signal indicating the actuator to retract the fluid-drag reduction system.

[0049] In examples, deploying the fluid-drag reduction system can include transitioning the fluid-drag reduction system from a fully retracted configuration to a fully deployed configuration, and wherein retracting the fluid-drag reduction system can include transitioning the fluid-drag reduction system from the fully deployed configuration to the fully retracted configuration.

[0050] Consistent with the disclosed examples, a method is disclosed. In an example, the method can include receiving position data associated with a current location and a timestamp associated with the position data, a destination location, a departure location, data indicative of a predetermined area associated with the destination location, and data indicative of a predetermined area associated with the departure location. Additionally the method can include, determining, based on the position data, whether the current location is within the predetermined area associated with the destination location, and in response to determining that the current location is within the predetermined area associated with the destination location: transmitting, to an actuator, a signal indicating the actuator to retract a fluid-drag reduction system, in response to determining that the current location is not within the predetermined area associated with the destination location: determining whether the current location is within the predetermined area associated with the departure location, and in response to determining that the current location is within the predetermined area associated with the departure location: transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system, in response to determining that the current location is not within the predetermined area associated with the departure location, and transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system.

[0051] In examples, the method can include receiving, from a GPS transceiver, the position data associated with the current location and the timestamp associated with the position data, and receiving, from a server via a network, the destination location, the departure location, the data indicative of a predetermined area associated with the destination location, and the data indicative of a predetermined area associated with the departure location.

[0052] In examples, the method can include receiving, at a user interface, a first user input indicative of the position data associated with a current location and the timestamp associated with the position data. Additionally the method can include, receiving, at the user interface, a second user input indicative of a destination location, and a third user input indicative of a departure location, and generating, using one or more processors, data indicative of a predetermined area associated with the departure location, and data indicative of a predetermined area associated with the destination location.

[0053] Consistent with the disclosed examples, a method is disclosed. In an example, the method can include receiving, via a network or an on-board sensor, hyper-local weather data associated with a predetermined area around a current location, position data associated with the current location, a timestamp associated with the position data, a destination location, a departure location, data indicative of a predetermined area associated with the destination location, and data indicative of a predetermined area associated with the departure location, determining, based on the position data, whether the current location is located within the predetermined area associated with the destination location, and in response to determining that the current location is located within the predetermined area associated with the destination location: transmitting, to an actuator, a signal indicating the actuator to retract a fluid-drag reduction system, in response to determining that the current location is not located within the predetermined area associated with the destination location: determining whether the current location is located within the predetermined area associated with the departure location, and in response to determining that the current location is located within the predetermined area associated with the departure location: transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system, in response to determining that the current location is not within the predetermined area associated with the departure location: determining, based on the hyper-local weather data, whether the fluid-drag reduction system’s safe operation limits will be exceeded, in response to determining that the fluid-drag reduction system’s safe operation limits will be exceeded: transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system, in response to determining that the fluid- drag reduction system’s safe operation limits will not be exceeded: transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system.

[0054] In examples, vehicle properties can include at least one of: a table of tire coefficients of frictions, vehicle weight, vehicle weight distribution, vehicle dimensions, vehicle surface area, number of axles, damping coefficients for the vehicle’s suspension system, and table-tilt alpha value.

[0055] In examples, the hyper-local weather data can include at least one of: current wind speed, current wind speed direction, current wind gust, current wind gust direction, current precipitation category, current precipitation rate, average wind speed, average wind speed direction, average wind gust, average wind gust direction, average precipitation category, average precipitation rate, historical wind speed, historical wind speed direction, historical wind gust, historical wind gust direction, historical precipitation category, historical precipitation rate, forecasted wind speed, forecasted wind speed direction, forecasted wind gust, forecasted wind gust direction, forecasted precipitation category, or forecasted precipitation rate.

[0056] In examples, determining, based on the hyper-local weather data, whether the fluid- drag reduction system’s safe operation limits will be exceeded can include calculating a wind speed perpendicular to the vehicle’s direction of travel or a wind gust perpendicular to the vehicle’s direction of travel, interpolating a coefficient of friction (CoF) based on the hyper local weather data, determining, based on vehicle properties and the interpolated CoF, a wind speed threshold or a wind gust threshold above which operation of the fluid-drag reduction system in a fully deployed configuration is unsafe. Additionally the method can include, determining, based on the hyper-local weather data, an excessive wind gust probability of a wind gust exceeding the wind gust threshold or an excessive wind speed probability of a wind speed exceeding the wind speed threshold, determining whether the excessive wind gust probability or the excessive wind speed probability exceed a user-configurable threshold above which the probability of the vehicle encountering wind speeds or wind gusts is considered unsafe to operate the fluid-drag reduction system in the fully deployed configuration, and in response to determining that the excessive wind gust probability or the excessive wind speed probability exceed a user-configurable threshold, transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system, in response to determining that the excessive wind gust probability or the excessive wind speed probability does not exceed a user-configurable threshold, and transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system.

[0057] Consistent with the disclosed examples, a method is disclosed. In an example, the method can include receiving, from a first relay in communication with a microcontroller and a first indication light of a vehicle, a signal indicating an active state of the first relay, receiving, from a second relay in communication with the microcontroller and a second indication light of the vehicle, a signal indicating an active state of the second relay. Additionally the method can include, determining that the active states of the first relay and the second relay are received synchronously, and transmitting, to an actuator, a signal to retract a fluid-drag reduction system.

[0058] In examples, the first indication light can be at least one of: a first turn light or a first reverse light.

[0059] In examples, the second indication light is at least one of: a second reverse light or a second turn light.

[0060] In examples, receiving, from a position sensor in communication with the microcontroller, a signal indicating the fluid-drag reduction system is in a fully retracted configuration, and transmitting, to the actuator, a signal that indicates to the actuator to halt retraction of the fluid-drag reduction system. [0061] In examples, the first relay can be wired in a parallel configuration with the first indication light.

[0062] Further features of the disclosed design, and the advantages offered thereby, are explained in greater detail hereinafter with reference to specific examples illustrated in the accompanying drawings, wherein like elements are indicated be like reference designators.

BRIEF DESCRIPTION OF THE DRAWINGS

[0063] Reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and which are incorporated into and constitute a portion of this disclosure, illustrate various implementations and aspects of the disclosed technology and, together with the description, serve to explain the principles of the disclosed technology. In the drawings:

[0064] FIGs. 1A-1F illustrate aspects of an example fluid-drag reduction system in a fully deployed configuration, according to aspects of the present disclosure.

[0065] FIGs. 1G-1J illustrate aspects of an example fluid-drag reduction system in a fully retracted configuration, according to aspects of the present disclosure.

[0066] FIGs. 2A and 2B illustrate aspects of an example controls system, according to present disclosure.

[0067] FIG. 3 is a flowchart of an example method for operating an example fluid-drag reduction system, according to present disclosure.

[0068] FIG. 4 is a flowchart of an example method for operating an example fluid-drag reduction system, according to present disclosure.

[0069] FIGs. 5A and 5B are flowcharts of an example method for operating an example fluid- drag reduction system, according to present disclosure.

[0070] FIGs. 6A and 6B are flowcharts of an example method for operating an example fluid- drag reduction system.

[0071] It is noted that the drawings of the disclosure are not to scale. The drawings are intended to depict only typical aspects of the disclosure, and therefore should not be considered as limiting the scope of the disclosure. In the drawings, like numbering represents like elements between the drawings. DETAILED DESCRIPTION

[0072] Some implementations of the disclosed technology will be described more fully with reference to the accompanying drawings. This disclosed technology may, however, be embodied in many different forms and should not be construed as limited to the implementations set forth herein. The components described hereinafter as making up various elements of the disclosed technology are intended to be illustrative and not restrictive. Many suitable components that would perform the same or similar functions as components described herein are intended to be embraced within the scope of the disclosed electronic devices and methods. Such other components not described herein may include, but are not limited to, for example, components developed after development of the disclosed technology.

[0073] It is also to be understood that the mention of one or more method steps does not preclude the presence of additional method steps or intervening method steps between those steps expressly identified. Similarly, it is also to be understood that the mention of one or more components in a device or system does not preclude the presence of additional components or intervening components between those components expressly identified.

[0074] In an example, a fluid-drag reduction system that can be configured to (i) mount to a vehicle, and (ii) transition between a first configuration and a second configuration independent of a door system and can include a fairing system. The fairing system can include a fairing that can be configured to transition between a first position in the first configuration of the fluid- drag reduction system and a second position in the second configuration of the fluid-drag reduction system.

[0075] In an example, a method for transitioning a fluid-drag reduction system between a first and second configuration can include the method can include receiving, from a GPS transceiver, position data associated with a current location and a timestamp associated with the position data, and determining, using one or more processors, a speed based on the position data, the timestamp, previous position data, and previous timestamp. Additionally the method can include, determining, using the one or more processors, whether the speed is greater than a user-configurable threshold, and in response to determining that the speed is greater than the user-configurable threshold, transmitting, to an actuator, a signal indicating the actuator to deploy a fluid-drag reduction system.

[0076] In an example, a method for transitioning a fluid-drag reduction system between a first and second configuration can include the method can include receiving, from a first relay in communication with a microcontroller and a first indication light of a vehicle, a signal indicating an active state of the first relay, receiving, from a second relay in communication with the microcontroller and a second indication light of the vehicle, a signal indicating an active state of the second relay. Additionally the method can include, determining that the active states of the first relay and the second relay are received synchronously, and transmitting, to an actuator, a signal to retract a fluid-drag reduction system.

[0077] In an example, a method for transitioning a fluid-drag reduction system between a first and second configuration can include the method can include receiving, via a network or an on-board sensor, hyper-local weather data associated with a predetermined area around a current location, position data associated with the current location, a timestamp associated with the position data, a destination location, a departure location, data indicative of a predetermined area associated with the destination location, and data indicative of a predetermined area associated with the departure location, determining, based on the position data, whether the current location is located within the predetermined area associated with the destination location, and in response to determining that the current location is located within the predetermined area associated with the destination location: transmitting, to an actuator, a signal indicating the actuator to retract a fluid-drag reduction system, in response to determining that the current location is not located within the predetermined area associated with the destination location: determining whether the current location is located within the predetermined area associated with the departure location, and in response to determining that the current location is located within the predetermined area associated with the departure location: transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system, in response to determining that the current location is not within the predetermined area associated with the departure location: determining, based on the hyper local weather data, whether the fluid-drag reduction system’s safe operation limits will be exceeded, in response to determining that the fluid-drag reduction system’s safe operation limits will be exceeded: transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system, in response to determining that the fluid-drag reduction system’s safe operation limits will not be exceeded: transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system.

[0078] In an example, a method for transitioning a fluid-drag reduction system between a first and second configuration can include receiving position data associated with a current location and a timestamp associated with the position data, a destination location, a departure location, data indicative of a predetermined area associated with the destination location, and data indicative of a predetermined area associated with the departure location. Additionally the method can include, determining, based on the position data, whether the current location is within the predetermined area associated with the destination location, and in response to determining that the current location is within the predetermined area associated with the destination location: transmitting, to an actuator, a signal indicating the actuator to retract a fluid-drag reduction system, in response to determining that the current location is not within the predetermined area associated with the destination location: determining whether the current location is within the predetermined area associated with the departure location, and in response to determining that the current location is within the predetermined area associated with the departure location: transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system, in response to determining that the current location is not within the predetermined area associated with the departure location, and transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system.

[0079] Reference will now be made in detail to examples of the disclosed technology, examples of which are illustrated in the accompanying drawings and disclosed herein. Wherever convenient, the same references numbers will be used throughout the drawings to refer to the same or like parts.

[0080] FIGs. 1A-1F illustrate an example of a fluid-drag reduction system 100 in a first configuration. The components and arrangements shown in FIGs. 1A-1F are not intended to limit the disclosed examples as the components used to implement the disclosed processes and features may vary. Turning to FIG. 1A, the fluid-drag reduction system 100 can be configured to be operable on a vehicle 1 including a first side 2a, a second side 2b, a rear portion 3, an undercarriage 4, and a door system 5. The door system 5 can be any door configuration, for example, a roll door, a hinged double-door, door within a door, and/or a swing door. Additionally or alternatively, the door system 5 can include latches configured to secure the door. The fluid-drag reduction system 100 can be operable to transition between a first and second configuration independent of either: (i) the door configurations and/or the latch configurations. The rear portion 3 of the vehicle 1 can include portions of the first side 2a, the second side 2b, the door system 5, and/or the undercarriage 4. Further, the vehicle 1 can include one or more indication lights, for example, turn lights or reverse lights. The fluid-drag reduction system 100 can further include a fairing system 200, a motion-control system 300, and an attachment system 400. Additionally, the fluid-drag reduction system 100 can include a controls system 500. In an example, the first configuration of the fluid-drag reduction system 100 can be a deployed configuration. In another example, the first configuration of the fluid- drag reduction system 100 can be a fully deployed configuration. A length that the fairing system 200 extends beyond the rear portion 3 of the vehicle 1 can be referred to herein as an overhang length A. In the deployed configuration of the fluid-drag reduction system 100, the overhang length A of the fairing system 200 can be six inches or greater beyond the rear portion 3 of the vehicle 1. In the fully deployed configuration of the fluid-drag reduction system 100, the overhang length A of the fairing system 200 can extend seventeen inches or greater beyond the rear portion 3 of the vehicle 1. Additionally or alternatively, in the fully deployed configuration of the fluid-drag reduction system 100, the overhang length A of the fairing system 200 can extend between seventeen inches to eighty- four inches beyond the rear portion 3 of the vehicle 1. Additionally or alternatively, in the fully deployed configuration of the fluid- drag reduction system 100, the overhang length A of the fairing system 200 can extend between forty-eight inches to seventy -two inches beyond the rear portion 3 of the vehicle 1. The overhang length A of the fairing system 200 is important to reducing the drag on the vehicle since longer lengths have shown increased reduction in drag.

[0081] Turning to FIGs. IB- IF, the fairing system 200 can include a first fairing 201, which can include a first panel 202, a first upper member 203 a, a first lower member 203b, a first trailing member 204a, and a first leading member 204b. Additionally, the fairing system 200 can include a second fairing 205, which can include, a second panel 206, a second upper member 207a, a second lower member 207b, a second trailing member 208a, and a second leading member 208b. Additionally or alternatively, the first fairing 201 and/or second fairing 205 can include fairing guide edges configured to be slideably positioned within, for example, a groove of the guide rails 402a-d, discussed in detail below. Additionally or alternatively, the fairing guide edges can be the first upper member and/or second upper member 203a, 207a. Additionally or alternatively, the fairing guide edges can be the first lower member and/or second lower member 203b, 207b.

[0082] The fairing system 200 can be located proximate the rear portion 3 of the vehicle 1. Additionally or alternatively, the fairing system 200 can be located proximate the first and/or second side 2a of the vehicle 1. Additionally or alternatively, the fairing system 200 can be configured to detachably attach to a vehicle 1 , and can be configured to operate independent of the door system 5. Alternatively, the fairing system 200 can be configured to attach to a vehicle 1, and can be configured to operate independent of the door system 5. Additionally, the fairing system 200 can be in communication with the motion-control system 300, the attachment system 400, and/or the controls system 500.

[0083] Alternatively, the fairing system 200 can include a first fairing 201 , which can include a first panel 202, a first trailing member 204a, and a first leading member 204b. Additionally, the fairing system 200 can further include a second fairing 205, which can include, a second panel 206, a second trailing member 208a, and a second leading member 208b.

[0084] The first upper member 203 a, the first lower member 203b, the first trailing member 204a, and the first leading member 204b can be each be attached to one another to form a substantially rectangular frame about the first panel 202. The first upper member 203a, the first lower member 203b, the first trailing member 204a, and the first leading member 204b can be constructed from one or more of: a glass-fiber composite, a carbon-fiber composite, stainless steel, aluminum, or other materials suitable for structural applications.

[0085] Alternatively, the first trailing member 204a, and the first leading member 204b can be each be attached to the first panel 202 to provide additional support to the first panel 202. The first trailing member 204a, and the first leading member 204b can be constructed from one or more of: a glass-fiber composite, a carbon-fiber composite, stainless steel, aluminum, or other materials suitable for structural applications.

[0086] The second upper member 207a, the second lower member 207b, the second trailing member 208a, and the second leading member 208b can be each be attached to one another to form a substantially rectangular frame about the second panel 206. The second upper member 207a, the second lower member 207b, the second trailing member 208a, and the second leading member 208b can be constructed from one or more of: a glass-fiber composite, a carbon-fiber composite, stainless steel, aluminum, or other materials suitable for structural applications.

[0087] Alternatively, the second trailing member 208a, and the second leading member 208b can be each be attached to the second panel 206 to provide additional support to the second panel 206. The second trailing member 208a, and the second leading member 208b can be constructed from one or more of: a glass-fiber composite, a carbon-fiber composite, stainless steel, aluminum, or other materials suitable for structural applications.

[0088] The first and second panels 202, 206 can be constructed from one or more of: boating shrink film, a glass-fiber composite, canvas, sailcloth or other suitable materials. Suitable materials can include one or more of the following material properties: flexibility under high loads, durability against punctures or tears, resistance to degradation by ultraviolet light, hydrophobicity, or resistant to elongation over time. Additionally or alternatively, the first and second panels 202, 206 can be constructed from a foam-aluminum composite that includes a first aluminum sheet, a second aluminum sheet, and polyethylene foam core disposed therebetween, a carbon-fiber composite, and/or other suitable materials. The foam core can be one or more of: a solid core, a honeycomb core, or the like. The first and second panels 202, 206 can be substantially rectangular. Alternatively, the first and second panels 202, 206 can be a variety of shape including, a circle, an ellipse, a square, a trapezoid, or other polygons. Additionally or alternatively, portions of the first and second panels 202, 206 can be patterned to include a rougher or smoother surface. Additionally or alternatively, portions of the first and second panels 202, 206 can be deformed to form a curved surface having, for example, a wavy profile, a parabolic profile, or other profiles suitable to reduce fluid drag. Additionally or alternately, the first and second panels 202, 206 can be tensioned to deform into a curved surface having, for example, a wavy profile, a parabolic profile, or other profiles suitable to reduce fluid drag. It will be appreciated that aerodynamic or hydrodynamic profiles, such as, smooth, curved surfaces are advantageous for reducing fluid drag.

[0089] Additionally or alternatively, the fairing 201 can transition between the first and second positions along an arcuate path. The arcuate path can include a radius of curvature defined by a one or more tension members 307a-d. One or more tension members 307a-d can include a fixed length L defining the radius of curvature for the arcuate path, a first end 307e pivotably attached to the fairing 201, and a second end 307f pivotably attached to the vehicle, thereby causing the fairing 201 to transition along the arcuate path. Additionally or alternatively, the first end 307e can be pivotably attached to the first trailing member 204a, thereby pulling the fairing 201 into the arcuate path. One or more tension members 307a-d can be attached likewise. The arcuate path can be parabolic, exponential, logarithmic, hyperbolic, or the like. Additionally or alternatively, the arcuate path can include one or more radii of curvature to define polynomic or sinusoidal paths.

[0090] Additionally or alternatively, the second fairing 205 can transition between first and second positions along a second arcuate path. The second arcuate path can include a radius of curvature defined by a one or more tension members 307a-d. One or more tension members 307a-d can include a fixed length L defining the radius of curvature for the second arcuate path, a first end 307e pivotably attached to the second fairing 205, and a second end 307f pivotably attached to the vehicle, thereby causing the fairing 205 to transition along the second arcuate path. The second arcuate path can be parabolic, exponential, logarithmic, hyperbolic, or the like. Additionally or alternatively, the second arcuate path can include one or more radii of curvature to define polynomic or sinusoidal paths. Additionally or alternatively, the second arcuate path can a mirror image of the first arcuate path.

[0091] The motion-control system 300 can be in communication with the fairing system 200, the attachment system 400, and/or the controls system 500. The motion-control system 300 can be attached to the vehicle 1. In an example, the motion-control system 300 can be attached to the rear portion 3 of the vehicle 1. In an example, the motion-control system 300 can be attached to the undercarriage 4 of the vehicle 1. In an example, the motion-control system 300 can be attached to either the inside or outside surface of the first or second side 2a of the vehicle 1. Additionally, the motion-controls system 300 can be configured to receive instructions and/or signals from the control systems 500. The motion-control system 300 can be configured to transition of the fluid-drag reduction system 100 between the first and the second configurations. Additionally or alternatively, the motion-control system 300 can be activated and/or deactivated by a user-controlled switch. Additionally or alternatively, the motion- control system 300 can be configured to receive portions of the fairing system 200. Additionally or alternatively, the motion-control system 300 can be configured to support portions of the fairing system 200

[0092] The motion-controls system 300 can include a first actuator 302a, a second actuator 302b, a first cord retaining device 304a which can be in communication with the first actuator 302a, a second cord retaining device 304b which can be in communication with the second actuator 302b, a first network of pulleys 306a, a second network of pulleys 306b, a first cord 308a, and a second cord 308b. In an example, one or more rotations of the first cord retaining device 304a and/or the second cord retaining device 304b in a first direction can transition the fluid-drag reduction system 100 from the first configuration to the second configuration. In an example, one or more rotations of the first cord retaining device 304a and/or the second cord retaining device 304b in a second direction can transition the fluid-drag reduction system 100 from the second configuration to the first configuration. The cord can include at least one of: chain or cable, a combination of chain and cable is contemplated by using adaptors to attach a length of chain to a length of cable. The first cord retaining device 304a can be at least one of: a gear, a sprocket, and/or a spool. The second cord retaining device 304b can be at least one of: a gear, a sprocket, and/or a spool. The first actuator 302a can be at least one of: a motor, a stepper motor, and/or a servo motor. The second actuator 302b can be at least one of: a motor, a brush DC motor, a brushless DC motor, a stepper motor, and/or a servo motor. The first and/or second network of pulleys 306a, 306b can be arranged in any configuration to cause motion induced by one or more rotations of the first and/or second actuator 302a, 302b to at least the fairing system 200, thereby transitioning the fluid-drag reduction system 100 between the first and second configurations.

[0093] Alternatively, the motion-controls system 300 can include a first actuator 302a (e.g., an actuator 302a) , a first cord retaining device 304a (e.g., a cord retaining device 304a) which can be in communication with the first actuator 302a, a first network of pulleys 306a (e.g., a network of pulleys 306a) , and a first cord 308a (a cord 308a). In an example, one or more rotations of the first cord retaining device 304a and/or the second cord retaining device 304b in a first direction can transition the fluid-drag reduction system 100 from the first configuration to the second configuration. In an example, one or more rotations of the first cord retaining device 304a and/or the second cord retaining device 304b in a second direction can transition the fluid-drag reduction system 100 from the second configuration to the first configuration.

[0094] Additionally or alternatively, the motion control system 300 can include one or more pneumatic actuators 310a-d, located proximate one or more guide rails, for example, a first guide rail 402a, a second guide rail 402b, a third guide rail 402c, and a fourth guide rail 402d of the attachment system 400. One or more pneumatic actuators 310a-d can be in communication with an air compressor 312 attached to the vehicle 1. Alternatively, one or more pneumatic actuators 31 Oa-d can be in communication with an air- line of the vehicle 1. Additionally or alternatively, the pneumatic actuators 31 Oa-d, can be behind each rail that could extend about six feet, which can be approximately 3/4ths of the length of the one or more guide rails 402a-d. The pneumatic actuators 31 Oa-d could be approximately the same diameter as the guide rails 402a-d.

[0095] Additionally or alternatively, the motion-control system 300 can include one or more lead screws 314a, 314b in communication with one or more guide rails, for example, the first guide rail 402a, the second guide rails 402b, the third guide rail 402c, and the fourth guide rails 402d. The actuation of one or more lead screws 314a, 314b can transition the first fairing 201 and/or second faring 205 between the first configuration and the second configuration of the fluid-drag reduction system 100. Each lead screw 314a, 314b can be actuated by a stepper actuator which can be attached to an end of the lead screw 314a, 314b. One or more threaded sleds 316a, 316b can be in communication with the first upper and lower members 203a, 203b, and/or the second upper and lower member 207a, 207b. One or more threaded sleds 316a, 316b can be in communication with one or more lead screws 314a, 314b and/or one or more guide rails 402a-d, and transition the first fairing 201 and/or the second fairing 205 between the first and second configurations of the fairing system 200. Alternatively, the lead screws 314a, 314b can be ball screws.

[0096] Turning to FIG. IF, alternatively, the motion-controls system 300 can include a first actuator 302a (e.g., actuator 302a), a housing 301, a first cord retaining device 304a which can be within the housing 301 and in communication with the first actuator 302a by way of a first and/or second cord 308a, 308b, a second cord retaining device 304b which can be within the housing 301 and in communication with the first actuator 302a by way of a first and/or second cord 308a, 308b, a first cord 308a in communication with the first and/or second cord retaining device 304a, 304b and/or the first actuator 302a. The second cord 308b in communication with the first and/or second cord retaining device 304a, 304b, and/or first actuator 302a. In an example, one or more rotations of the first actuator 302a in a first direction can transition the fluid-drag reduction system 100 from the first configuration to the second configuration. In an example, one or more rotations of the first actuator 302a in a second direction can transition the fluid-drag reduction system 100 from the second configuration to the first configuration. Additionally, one or more rotations in the first direction of the first actuator 302a can cause one or more rotations of the first and/or second cord retaining device 304a, 304b, by way of the first and/or second cord 308a, 308b. The first and/or second cord retaining device 304a, 304b can rotate in the first direction. Alternatively, the first and/or second cord retaining device 304a, 304b can rotate in a second direction. Alternatively, the first and/or second cord retaining device 304a, 304b can rotate in independent directions. The first and/or second cords 308a, 308b, can be a combination of chain and/or cable by first and second connection points 309a, 309b. Connection points 309a, 309b can be at least one of: attachment adaptors, or connection adaptors. Connection points 309a, 309b can be located on the first cord 308a or the second cord 308b. Alternatively, a first connection point 309a can be located on the first cord 308a, and a second connection point 309b can be located on the second cord 308b. The housing 301 can be made from one or more of: aluminum, stainless steel, plastic, glass-fiber, and/or carbon-fiber composites.

[0097] Turning back to FIGs. 1B-1F, the attachment system 400 can be attached to the vehicle 1. Additionally or alternatively, the attachment system 400 can be attached to a first and/or second side 2a of the vehicle 1. Additionally or alternatively, the attachment system 400 can be attached to the rear portion 3 of the vehicle 1. Additionally or alternatively, the attachment system 400 can be configured to receive portions of the fairing system 200. Additionally or alternatively, the attachment system 400 can be configured to support portions of the fairing system 200. Additionally or alternatively, the attachment system 400 can be configured to moveably retain the fairing system 200 on the vehicle 1. Additionally or alternatively, the attachment system 400 can be in communication with the fairing system 200, motion-control system 300, and/or the controls system 500, and can support and/or guide the fluid-drag reduction system 100 while it transitions between at least the first and second configurations. Additionally or alternatively, the portions of the attachment system 400 can be integral to the vehicle 1, for example, guide rails 402a-d. Additionally or alternatively, the guide rails 402a-d can be bolted on to the vehicle 1.

[0098] The attachment system 400 can include one or more guide rails 402a-d, for example, the first guide rail 402a, the second guide rail 402b, the third guide rail 402c, and the fourth guide rail 402d. The one or more guide rails 402a-d can have a substantially “J” profile, defining a groove within which fairing guide edges can be positioned and operable to slide. The one or more guide rails 402a-d can made of: stainless steel, aluminum, composites, or other suitable materials. The one or more guide rails 402a-d can be attached to the first side 2a of the vehicle 1 and/or the second side 2b of the vehicle 1. The guide rails 402a-d can support and/or mount the fairing system 200 to the vehicle 1.

[0099] The controls system 500 can include a microcontroller 502, a global positioning system (GPS) transceiver 504, an onboard sensor 505, a first position sensor 506a, a second position sensor 506b, a first relay 508a, and/or a second relay 508b. Alternatively, the controls system 500 can include a global positioning system (GPS) transceiver 504, an onboard sensor 505, a first position sensor 506a, and/or a first relay 508a. The onboard sensor 505 can be a non-vehicular sensor comprising one or more of: a force sensor, a radar, a camera, an IR camera, or an ultrasonic proximity sensor, and configured to transmit to data and receive data from the microcontroller 502. The first and/or second position sensors 506a, 506b can be one or more of: a limit switch, an infrared proximity sensor, encoder, or the like. The GPS transceiver 504, the first and/or second position sensors 506a, 506b, and the first and second relays 508a, 508b, can be in communication with the microcontroller 502. Additionally, the controls system 500 can be in communication with other systems, for example, the motion- control system 300. Additionally, the controls system 500 can include a power source, for example, a battery to provide power to the controls system 500 and/or the motion-control system 300. Additionally or alternatively, the first and/or second position sensors 506a, 506b can be located proximate the first and second cords 308a, 308b, the first and second cords 308a, 308b configured to trigger the position sensors 506a, 506b. Additionally or alternatively, the first and/or second connection points 309a, 309b can be configured to trigger the first and/or second position sensors 506a, 506b. Additionally or alternatively, the first and/or second position sensors 506a, 506b can be associated with the first and/or second actuator 302a, 302b, for example, a servo and/or stepper motor. The relays 508a, 508b can be wired in parallel with the vehicle’s electrical system. The controls system 500 can be in communication with the vehicle’s electrical system, navigation system, infotainment system, voice-communication system, onboard computer system, data collection system, networking system, and/or diagnostic system. In an example, the controls system 500 can receive voice-commands from the operator other operators (for example pilot vehicle drivers) over the voice-communication system and can be configured to send instructions to the motion-control system 300 to either retract or deploy the fluid-drag reduction system 100. The controls system 500 can be configured to communicate with fluid-drag reduction systems on other vehicles. In an example, for semi-trailers driving in a “train” formation, the controls system on lead vehicle can communicate with the fluid-drag reduction system of each vehicle in the “train” and send instructions to each fluid-drag reduction system to either deploy or retract to maximize drag reduction of the entire “train”.

[00100] FIGs. 1G-1J are illustrations of a fluid-drag reduction system 100 in a second configuration. The components and arrangements shown in FIGs. 1G-1J are not intended to limit the disclosed examples as the components used to implement the disclosed processes and features may vary. The second configuration can be a retracted configuration. Additionally or alternatively, the second configuration can be a fully retracted configuration. In the retracted configuration, the overhang length A of the fairing system 200 can be less than six inches beyond the rear portion 3 of the vehicle 1. Additionally or alternatively, in a fully retracted configuration, the overhang length A of the fairing system 200 does not extend beyond the rear portion 3. Additionally or alternatively, in a fully retracted configuration, the overhang length A of the fairing system 200 does not extend greater than three inches beyond the rear portion 3 of the vehicle 1. Additionally or alternatively, in a fully retracted configuration, the overhang length A of the fairing system 200 does not extend greater than one inch beyond the rear of the vehicle. It will be appreciated by one of ordinary skill in light of the present disclosure that keeping the retracted configurations within three inches of the rear portion 3 of the vehicle 1 prevents incompatibility between the vehicle 1 and the dock, allowing for convenient loading and unloading of freight. Additionally or alternatively, intermediate positions between the first and second position are contemplated. Additionally or alternatively, intermediate configurations between the first and second configurations are contemplated.

[00101] FIGs. 2A and 2B are block diagrams of an example controls system 500. The controls system 500, as discussed earlier, can include a microcontroller 502, a global positioning system (GPS) transceiver 504, a first position sensor 506a, a second position sensor 506b, a first relay 508a, and a second relay 508b. Additionally, the controls system 500 can include a user interface 510. Additionally, the controls system 500 can include a power source, for example, a battery to provide power to the controls system 500 and/or the motion-control system 300. The battery can be in communication with the vehicle’s electrical system and can be trickle- charged using the same. The first and second relays 508a, 508b can be wired in parallel with the vehicle’s electrical system. Additionally or alternatively, the first relay 508a can be in communication with a first indication light of the vehicle 1. Additionally or alternatively, the second relay 508b can be in communication with a second indication light of the vehicle 1. Additionally or alternatively, the first relay 508a can be in communication with a first reverse light of the vehicle 1. Additionally or alternatively, the second relay 508b can be in communication with a second reverse light of the vehicle 1. The microcontroller 502 can be in communication with one or more actuators, for example, the first actuator 302a and second actuator 302b. Additionally or alternatively, the microcontroller 502 can send the same instructions to each actuator. Additionally or alternatively, the microcontroller can send different instructions to each actuator 302a, 302b. It will be understood that different signals and instructions can be sent and received to and from different components in communication with the microcontroller 502.

[00102] The microcontroller 502 is not so limited and can be in communication with one or more actuators, one or more position sensors, one or more force sensors, one or more relays, one or more onboard sensors, one or more networks, one or more user interfaces, one or more near-field communication networks, one or more GPS transceivers, and/or one or more servers. The microcontroller 502 can include memory 503 a, configured to store instructions and/or one or more databases, one or more processors 503b, one or more networking interfaces 503 c configured to be in communication with one or more networks and configured to send and receive data over one or more networks, and an I/O interface 503 d that can be configured to send and receive instruction from one or more user inputs, transceivers, actuators or the like. Additionally or alternatively, the microcontroller 502 can be in communication with a plurality of microcontrollers and/or a plurality of motion-control systems. The microcontroller 502, can be configured to send and receive trip information data and /or vehicle information data from the server 602 of the backend system 600 over a network 6 and using the networking interface 503c. The microcontroller 502, can be configured to send and receive hyper-local weather data and /or vehicle properties data from the server 602 of the backend system 600 over a network 6 and using the networking interface 503 c. Additionally or alternatively, a first portion of the hyper-local weather data, vehicle properties data, trip information data, or vehicle information data can be sent or received from the server 602 of the backend system 600 over a network 6 and using the networking interface 503 c and a second portion of the hyper-local weather data, vehicle properties data, trip information data, or vehicle information data can be sent or received from at least one of: one or more sensors 505, GPS transceiver 504, user interfaces 510, or the like. Additionally or alternatively, the microcontroller 502 can be in communication with a user-activated device. The user-activated device, upon being triggered, can transmit a signal, via wired or wireless means, to the microcontroller 502, causing the microcontroller 502 to transmit, to the first actuator 302a and/or second actuator 302b , a signal to retract the fluid-drag reduction system 100.

[00103] Additionally or alternatively, the microcontroller 502 can be in communication with a user-activated device. The user-activated device, upon being triggered, can transmit a signal, via wired or wireless means, to the microcontroller 502, causing the microcontroller 502 to transmit, to the first actuator 302a and/or second actuator 302b , a signal to deploy the fluid- drag reduction system 100.

[00104] Backend system 600 can include one or more servers 602. The server 602 can store trip information data and can include one or more of: a destination location, a departure location, geo-fence data associated with the destination location, geo-fence data associated with the departure location, trip distance data, estimated time of arrival data, route data, speed limit data associated with the route data, and/or weather data. Additionally, the server 602 can store vehicle information data can include one or more of: diagnostic data, for example, current draw for the first and/or second actuators 302a, 302b, force sensor data indicative of forces experienced by the fluid-drag reduction system 100, current state of the fluid-drag reduction system 100, vehicle speed data, vehicle current location data, old vehicle location data, error data associated with the fluid-drag reduction system 100. The server 602 is not so limited as it can be configured to deploy or execute various artificial intelligence and/or machine learning algorithms to improve accuracy of the data delivered to the fluid-drag reduction system 100 and/or make inferences based on the data. In an example, the server 602 can improve the location resolution of hyper- local weather data delivered to the fluid-drag reduction system 100 by using machine learning algorithms and existing hyper-local weather data. In another example, the server 602 can improve the accuracy of hyper- local weather forecasts delivered to the fluid-drag reduction system 100 by using machine learning algorithms and existing hyper-local weather data.

[00105] FIG. 3 is a flowchart of a method 700 of transitioning a fluid-drag reduction system (e.g., fluid-drag reduction system 100) between the first and second configuration, according to an example.

[00106] At block 702, the method can include receiving, from a first relay (e.g., first relay 508a) in communication with the microcontroller and a first indication light of a vehicle, a signal indicating an active state of the first relay. Additionally or alternatively, the first indication light of the vehicle can be a first reverse light or a first turn light. Additionally or alternatively, the first relay can be wired in a parallel configuration with the first indication light. Additionally or alternatively, the method can include receiving, from a second relay (e.g., second relay 508b) in communication with the microcontroller and a second indication light of the vehicle, a signal indicating an active state of the second relay. Additionally or alternatively, the second indication light of the vehicle can be a second reverse light of the vehicle or second turn light of the vehicle. Additionally or alternatively, the second relay can be wired in a parallel configuration with the second indication light. Additionally or alternatively, the method can include receiving one or more signals from the first and second relays simultaneously or synchronously.

[00107] At block 704, the method can include determining that the first relay and the second relay are synchronously in active states. Additionally or alternatively, the first relay and second relay can be in active states simultaneously. Additionally or alternatively, the first and second relay can be toggling between active and deactive states synchronously or simultaneously.

[00108] At block 706, the method can include transmitting, to an actuator (e.g., actuator 302a), a signal to retract a fluid-drag reduction system. Additionally or alternatively, the microcontroller can receive, from a position sensor (e.g., first position sensor 506a) in communication with the microcontroller, a signal indicating the fluid-drag reduction system is in a fully retracted configuration. Additionally or alternatively, the microcontroller can transmit, to the actuator, a signal that indicates to the actuator to halt retraction of the fluid- drag reduction system. Additionally or alternatively, the microcontroller can transmit, to a user interface (e.g., user interface 510), an indication that the fluid-drag reduction system is in a fully retracted configuration. Additionally or alternatively, retracting the fluid-drag reduction system can include transitioning the fluid-drag reduction system from the first configuration to the second configuration. Additionally or alternatively, deploying the fluid-drag reduction system can include transitioning the fluid-drag reduction system from the second configuration to the first configuration.

[00109] Additionally or alternatively, a user-activated device can, upon activation (i.e. triggering), transmit a signal to the microcontroller to cause the microcontroller to transmit, to an actuator, a signal to retract the fluid-drag reduction system.

[00110] Additionally or alternatively, the user-activated device can, upon activation, transmit a signal to the microcontroller to cause the microcontroller to transmit, to an actuator, a signal to deploy the fluid-drag reduction system.

[00111] FIG. 4 is a flowchart of a method 800 of transitioning the fluid-drag reduction system (e.g. fluid-drag reduction system 100) between the first and second configurations, according to an example.

[00112] At block 802, the method can include storing, on memory (e.g., memory 503a) associated with a microcontroller (e.g., microcontroller 502), old position data associated with a previous location and an old timestamp associated with the old position data. Additionally or alternatively, the old position data can be associated with a vehicle’s previous location.

[00113] At block 804, the method can include receiving, from a GPS transceiver (e.g., GPS transceiver 504), position data associated with a current location and a timestamp associated with the position data. Additionally or alternatively, the position data can be associated with a vehicle’s current location.

[00114] At block 806, the method can include determining, at the microcontroller and using one or more processors (e.g., processors 503b), a speed based on the position data, the timestamp, the old position data, and the old position data. In an example, the speed and/or velocity can be determined by taking a derivative (or difference) with respect to time of the position data.

[00115] At block 808, the method can include the microcontroller can determine, using the one or more processors, whether the speed is greater than a user-configurable threshold. Additionally or alternatively, the microcontroller can receive, via a network (e.g., network 6), the user-configurable threshold from a server (e.g., server 602).

[00116] At block 810, the method can include in response to determining that the speed is greater than the user-configurable threshold, the microcontroller can transmit, to an actuator, a signal to deploy a fluid-drag reduction system. Additionally or alternatively, the microcontroller can receive, from a position sensor in communication with the microcontroller, a signal indicating the fluid-drag reduction system is in a fully deployed configuration, and can transmit, to the actuator, a signal that indicates the actuator to halt deployment of the fluid-drag reduction system. Additionally or alternatively, retracting the fluid-drag reduction system can include transitioning the fluid-drag reduction system from the first configuration to the second configuration. Additionally or alternatively, deploying the fluid-drag reduction system can include transitioning the fluid-drag reduction system from the second configuration to the first configuration. Additionally or alternatively, the method can include in response to determining that the speed is not greater than the user-configurable threshold, the microcontroller can transmit, to an actuator, a signal to retract the fluid-drag reduction system. Additionally or alternatively, retracting the fluid-drag reduction system can include transitioning the fluid-drag reduction system from the first configuration to the second configuration. Additionally or alternatively, deploying the fluid-drag reduction system can include transitioning the fluid-drag reduction system from the second configuration to the first configuration.

[00117] Additionally or alternatively, a user-activated device can, upon activation, transmit a signal to the microcontroller to cause the microcontroller to transmit, to an actuator, a signal to retract the fluid-drag reduction system.

[00118] Additionally or alternatively, the user-activated device can, upon activation, transmit a signal to the microcontroller to cause the microcontroller to transmit, to an actuator, a signal to deploy the fluid-drag reduction system.

[00119] FIGs. 5 A and 5B is a flowchart of a method 900 of transitioning the fluid-drag reduction system (e.g., fluid-drag reduction system 100) between configurations, according to an example.

[00120] At block 902, the method can include receiving, via a network or an on-board sensor, hyper-local weather data associated with a predetermined area around a current location, position data associated with the current location, a timestamp associated with the position data, a destination location, a departure location, data indicative of a predetermined area associated with the destination location, and data indicative of a predetermined area associated with the departure location. Hyper-local weather data can include one or more of: current wind speed, current wind speed direction, current wind gust, current wind gust direction, current precipitation category, current precipitation rate, average wind speed, average wind speed direction, average wind gust, average wind gust direction, average precipitation category, average precipitation rate, historical wind speed, historical wind speed direction, historical wind gust, historical wind gust direction, historical precipitation category, historical precipitation rate, forecasted wind speed, forecasted wind speed direction, forecasted wind gust, forecasted wind gust direction, forecasted precipitation category, or forecasted precipitation rate.

[00121] At block 904, the method can include determining, based on the position data, whether the current location is within the predetermined area associated with the destination location.

[00122] At block 906, the method can include in response to determining that the current location is within the predetermined area associated with the destination location.

[00123] At block 908, the method can include transmitting, to an actuator, a signal indicating the actuator to retract a fluid-drag reduction system.

[00124] At block 910, the method can include in response to determining that the current location is not within the predetermined area associated with the destination location.

[00125] At block 912, the method can include determining whether the current location is within the predetermined area associated with the departure location.

[00126] At block 914, the method can include in response to determining that the current location is within the predetermined area associated with the departure location.

[00127] At block 916, the method can include transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system.

[00128] At block 918, the method can include in response to determining that the current location is not within the predetermined area associated with the departure location.

[00129] At block 920, the method can include determining, based on the hyper-local weather data, whether the fluid-drag reduction system’s safe operation limits will be exceeded. Additionally or alternatively, the method can include determining, based on the hyper-local weather data, whether the fluid-drag reduction system’s safe operation limits will be exceeded. Additionally or alternatively, the method can include calculating a wind speed perpendicular to the vehicle’s direction of travel or a wind gust perpendicular to the vehicle’s direction of travel. Additionally or alternatively, the method can include interpolating a coefficient of friction (CoF) based on the hyper-local weather data. Additionally or alternatively, the method can include determining, based on vehicle properties and the interpolated CoF, a wind speed threshold or a wind gust threshold above which operation of the fluid-drag reduction system in a fully deployed configuration is unsafe. Additionally or alternatively, the method can include determining, based on the hyper-local weather data, an excessive wind gust probability of a wind gust exceeding the wind gust threshold or an excessive wind speed probability of a wind speed exceeding the wind speed threshold. Additionally or alternatively, the method can include determining whether the excessive wind gust probability or the excessive wind speed probability exceed a user-configurable threshold above which the probability of the vehicle encountering wind speeds or wind gusts is unsafe to operate the fluid-drag reduction system in the fully deployed configuration, and in response to determining that the excessive wind gust probability or the excessive wind speed probability exceed a user-configurable threshold. Additionally or alternatively, the method can include transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system, in response to determining that the excessive wind gust probability or the excessive wind speed probability does not exceed a user-configurable threshold. Additionally or alternatively, the method can include transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system. Vehicle properties can include at least one of: a table of tire coefficients of frictions, vehicle weight, vehicle weight distribution, vehicle dimensions, vehicle surface area, number of axles, damping coefficients for the vehicle’s suspension system, and table-tilt alpha value.

[00130] At block 922, the method can include in response determining that to the fluid-drag reduction system’s safe operation limits will be exceeded. The system’s safe operation limits can environmental, material, or vehicular thresholds that, if exceed, can cause the fluid-drag reduction system to fail, break, detach, warp, or cause excessive and/or unpredictable wear on the fluid-drag reduction system. Additionally or alternatively, the system’s safe operation limit can be thresholds associated with the vehicle on which the fluid-drag reduction system is attached or mounted, for example, if it is determined that deploying the fluid-drag reduction system in a combination environment conditions and vehicle properties can cause the vehicle to fishtail, rollover, tilt, slide, and/or otherwise depart unpredictably or uncontrollably from a lane, thereby placing the operator of the vehicle or drivers of other vehicles in potential danger, it can be determined that the fluid-drag reduction system’s safe operation limits will be exceeded. Additionally or alternatively, the system’s safe operation limit can be thresholds associated with the vehicle on which the fluid-drag reduction system is attached or mounted, for example, if it is determined that deploying the fluid-drag reduction system on a vehicle having vehicle properties and/or design parameters can cause the vehicle to fishtail, rollover, slide, tilt, and/or otherwise depart unpredictably or uncontrollably from a lane, thereby placing the operator of the vehicle or drivers of other vehicles in potential danger, it can be determined that the fluid-drag reduction system’s safe operation limits will be exceeded. Additionally or alternatively, the system’s safe operation limit can be thresholds associated with the environment in which the fluid-drag reduction system is operating in, for example, if it is determined that deploying the fluid-drag reduction system in severe weather can cause the vehicle to fishtail, rollover, slide, tilt, and/or otherwise depart unpredictably or uncontrollably from a lane, or can cause the fluid-drag reduction system to fail, break, detach, warp, or cause excessive and/or unpredictable wear, thereby placing the operator of the vehicle or drivers of other vehicles in potential danger, it can be determined that the fluid-drag reduction system’s safe operation limits will be exceeded.

[00131] At block 924, the method can include transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system.

[00132] At block 926, the method can include in response to determining that the fluid-drag reduction system’s safe operation limits will not be exceeded.

[00133] At block 928, the method can include transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system.

[00134] Additionally or alternatively, a user-activated device can, upon activation, transmit a signal to the microcontroller to cause the microcontroller to transmit, to an actuator, a signal to retract the fluid-drag reduction system.

[00135] Additionally or alternatively, the user-activated device can, upon activation, transmit a signal to the microcontroller to cause the microcontroller to transmit, to an actuator, a signal to deploy the fluid-drag reduction system.

[00136] FIGs. 6A-6B is a flowchart of a method 1000 of transitioning the fluid-drag reduction system (e.g., fluid-drag reduction system 100) between the first and second configurations, according to an example.

[00137] At block 1002, the method can include receiving position data associated with a current location and a timestamp associated with the position data, a destination location, a departure location, data indicative of a predetermined area associated with the destination location, and data indicative of a predetermined area associated with the departure location. Additionally or alternatively, the method can include receiving, from a GPS transceiver, the position data associated with the current location and the timestamp associated with the position data, and receiving, from a server via a network, the destination location, the departure location, the data indicative of a predetermined area associated with the destination location, and the data indicative of a predetermined area associated with the departure location. Additionally or alternatively, the method can include receiving, at a user interface, a first user input indicative of the position data associated with a current location and the timestamp associated with the position data. Additionally or alternatively, the method can include receiving, at the user interface, a second user input indicative of a destination location, and a third user input indicative of a departure location. Additionally or alternatively, the method can include generating, using one or more processors, data indicative of a predetermined area associated with the departure location, and data indicative of a predetermined area associated with the destination location.

[00138] At block 1004, the method can include determining, based on the position data, whether the current location is within the predetermined area associated with the destination location.

[00139] At block 1006, the method can include in response to determining that the current location is within the predetermined area associated with the destination location.

[00140] At block 1008, the method can include transmitting, to an actuator, a signal indicating the actuator to retract a fluid-drag reduction system.

[00141] At block 1010, the method can include in response to determining that the current location is not within the predetermined area associated with the destination location.

[00142] At block 1012, the method can include determining whether the current location is within the predetermined area associated with the departure location.

[00143] At block 1014, the method can include in response to determining that the current location is within the predetermined area associated with the departure location.

[00144] At block 1016, the method can include transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system. [00145] At block 1018, the method can include in response to determining that the current location is not within the predetermined area associated with the departure location.

[00146] At block 1020, the method can include transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system.

[00147] Additionally or alternatively, a user-activated device can, upon activation, transmit a signal to the microcontroller to cause the microcontroller to transmit, to an actuator, a signal to retract the fluid-drag reduction system.

[00148] Additionally or alternatively, the user-activated device can, upon activation, transmit a signal to the microcontroller to cause the microcontroller to transmit, to an actuator, a signal to deploy the fluid-drag reduction system.

[00149] Certain examples and implementations of the disclosed technology are described above with reference to block and flow diagrams of systems and methods and/or computer program products according to examples or implementations of the disclosed technology. It will be understood that one or more blocks of the block diagrams and flow diagrams, and combinations of blocks in the block diagrams and flow diagrams, respectively, can be implemented by computer-executable program instructions. Likewise, some blocks of the block diagrams and flow diagrams can not necessarily need to be performed in the order presented, can be repeated, or can not necessarily need to be performed at all, according to some examples or implementations of the disclosed technology.

[00150] Accordingly, blocks of the block diagrams and flow diagrams support combinations of means for performing the specified functions, combinations of elements or steps for performing the specified functions, and program instruction means for performing the specified functions. It will also be understood that each block of the block diagrams and flow diagrams, and combinations of blocks in the block diagrams and flow diagrams, can be implemented by special-purpose, hardware-based computer systems that perform the specified functions, elements or steps, or combinations of special-purpose hardware and computer instructions.

[00151] In this description, numerous specific details have been set forth. It is to be understood, however, that implementations of the disclosed technology may be practiced without these specific details. In other instances, well-known methods, structures and techniques have not been shown in detail in order not to obscure an understanding of this description. References to “one embodiment,” “an embodiment,” “some embodiments,” “example embodiment,” “various embodiments,” “one implementation,” “an implementation,” “example implementation,” “various implementations,” “some implementations,” etc., indicate that the implementation(s) of the disclosed technology so described may include a particular feature, structure, or characteristic, but not every implementation necessarily includes the particular feature, structure, or characteristic. Further, repeated use of the phrase “in one implementation” does not necessarily refer to the same implementation, although it may.

[00152] Throughout the specification and the claims, the following terms take at least the meanings explicitly associated herein, unless the context clearly dictates otherwise. The term “connected” means that one function, feature, structure, or characteristic is directly joined to or in communication with another function, feature, structure, or characteristic. The term “coupled” means that one function, feature, structure, or characteristic is directly or indirectly joined to or in communication with another function, feature, structure, or characteristic. The term “or” is intended to mean an inclusive “or.” Further, the terms “a,” “an,” and “the” are intended to mean one or more unless specified otherwise or clear from the context to be directed to a singular form. By “comprising” or “containing” or “including” is meant that at least the named element, or method step is present in article or method, but does not exclude the presence of other elements or method steps, even if the other such elements or method steps have the same function as what is named.

[00153] As used herein, unless otherwise specified the use of the ordinal adjectives “first,” “second,” “third,” etc., to describe a common object, merely indicate that different instances of like objects are being referred to, and are not intended to imply that the objects so described must be in a given sequence, either temporally, spatially, in ranking, or in any other manner.

[00154] As used herein, unless otherwise specified the use of the adjective “secure”, “secured,” etc., is intended to mean non-permanently fixed or fastened so as not to give way, become loose, or be lost.

[00155] While certain examples of this disclosure have been described in connection with what is presently considered to be the most practical and various examples, it is to be understood that this disclosure is not to be limited to the disclosed examples, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation. [00156] This written description uses examples to disclose certain examples of the technology and also to enable any person skilled in the art to practice certain examples of this technology, including making and using any apparatuses or systems and performing any incorporated methods. The patentable scope of certain examples of the technology is defined in the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal language of the claims.

Claims

Claims What is claimed is:

1. A fluid-drag reduction system configured to (i) mount to a vehicle, and (ii) transition between a first configuration and a second configuration independent of a door system comprising: a fairing system comprising: a fairing configured to transition between a first position in the first configuration of the fairing system and a second position in the second configuration of the fairing system.

2. The fluid-drag reduction system of Claim 1, wherein the first configuration of the fluid- drag reduction system is a fully retracted configuration.

3. The fluid-drag reduction system of Claim 1, wherein the second configuration of the fluid-drag reduction system is a fully deployed configuration.

4. The fluid-drag reduction system of Claim 1, wherein the fluid-drag reduction system further comprises a third configuration between the first and second configurations of the fluid- drag reduction system.

5. The fluid-drag reduction system of Claim 1, further comprising: an attachment system configured to transition the fluid-drag reduction system between the first configuration and the second configuration, the attachment system comprising: an actuator configured to rotate a first gear in a first or second direction, thereby transitioning the fluid-drag reduction system between the first and second configurations; a cord configured to (i) rotate a second gear based on a rotation of the first gear, and (ii) attach to a cord at an connection point causing movement of the cord based on a rotation of the first gear thereby causing the fluid-drag reduction system to transition between the first and second configurations; and a network of pulleys configured to attach to the vehicle and configured to receive the cord.

6. The fluid-drag reduction system of Claim 5, further comprising a guide rail configured to (i) attach to a side of the vehicle and (ii) mount thereon, the fairing.

7. The fluid-drag reduction system of Claim 5, wherein the cord is a first cord and the connection point is a first connection point, and the attachment system further comprises: the cord configured to (i) rotate a third gear and (ii) attach to a second cord at a second connection point causing the second cord to move based on a rotation of the first gear thereby causing the fluid-drag reduction system to transition between the first and second configurations.

8. The fluid-drag reduction system of Claim 1, further comprising: an attachment system configured to transition the fluid-drag reduction system between the first configuration and the second configuration, the attachment system comprising: a network of pulleys configured to attach to the vehicle and configured to receive a cord comprising chain and cable; the cord in communication with the network of pulleys, a cord retaining device, and the fairing, the cord is operable to communicate one or more rotations of the cord retaining device to the fairing system thereby transitioning the fluid-drag reduction system between the first configuration and the second configuration; and an actuator configured to rotate the cord retaining device, the cord retaining device configured to retain the cord thereon.

9. The fluid-drag reduction system of Claim 1, further comprising: a mounting system comprising: a guide rail configured to (i) attach to a side of the vehicle and (ii) mount thereon, the fairing.

10. The fluid-drag reduction system of Claim 8, wherein the fairing is a first fairing and the fairing system further comprises: a second fairing configured to transition between the first position in the first configuration of the fluid-drag reduction system and the second position in the second configuration of the fluid-drag reduction system.

11. The fluid-drag reduction system of Claim 10, wherein the network of pulleys is a first network of pulleys; wherein the cord is a first cord; wherein the actuator is a first actuator; wherein the cord retaining device is a first cord retaining device; wherein the attachment system further comprises: a second network of pulleys configured to attach to the vehicle and configured to receive a second cord comprising cord and cord; the second cord in communication with the second network of pulleys, a second cord retaining device, and the second fairing, the second cord is operable to communicate one or more rotations of the second cord retaining device to the fairing system thereby transitioning the fluid-drag reduction system between the first configuration and the second configuration; and a second actuator configured to rotate the second cord retaining device, the second cord retaining device configured to retain the second cord thereon.

12. The fluid-drag reduction system of Claim 9 or 11, wherein the guide rail is a first guide rail; wherein the side of the vehicle is a first side of the vehicle; and wherein the mounting system further comprises a second guide rail in communication with the second cord and the second fairing, the second guide rail configured to (i) attach to a second side of the vehicle and (ii) mount thereon, the second fairing.

13. The fluid-drag reduction system of Claim 1, further comprising: a controls system comprising: a microcontroller in communication with a sensor and an actuator, the microcontroller configured to send or receive one or more of: sensor data or instructions to cause actuation of the actuator; the sensor configured to send or receive at least one of: data indicative of the fluid-drag reduction system being in the first configuration, position data, or data indicative of electrical current powering on a portion of a vehicle’s electrical system or powering off a portion of a vehicle’s electrical system; and the actuator configured to send or receive at least one of: instructions to deactivate the actuator or instructions to activate the actuator.

14. The fluid-drag reduction system of Claim 13, wherein the sensor is a position sensor configured to transmit data indicative of the fluid-drag reduction system being in the first configuration to the microcontroller.

15. The fluid-drag reduction system of Claim 13, wherein the sensor is a position sensor configured to transmit data indicative of the fluid-drag reduction system being in the second configuration to the microcontroller.

16. The fluid-drag reduction system of Claim 13, wherein the sensor is a relay configured to transmit data indicative of at least one of: a turn signal or a reverse light being in either an on-state or an off-state to the microcontroller.

17. The fluid-drag reduction system of Claim 13, wherein the sensor is a Global Positioning System (GPS) transceiver configured to transmit position data to the microcontroller.

18. The fluid-drag reduction system of Claim 13, wherein the sensor is a non- vehicular sensor comprising one or more of: a radar, a camera, an IR camera, or an ultrasonic proximity sensor, and configured to transmit data to the microcontroller.

19. The fluid-drag reduction system of Claim 13, wherein the actuator is a stepper motor configured to receive instructions to either activate or deactivate and transmit indexing data to the microcontroller.

20. The fluid-drag reduction system of Claim 1 , wherein the fairing transitions between the first and second positions along an arcuate path.

21. The fluid-drag reduction system of Claim 20, wherein the arcuate path comprising a radius of curvature defined by a tension member.

22. The fluid-drag reduction system of Claim 21, wherein the tension member comprising a fixed length defining the radius of curvature for the arcuate path, a first end pivotably attached to the fairing, and a second end pivotably attached to the vehicle, thereby causing the fairing to transition along the arcuate path.

23. The fluid-drag reduction system of Claim 1, further comprising a panel, the panel of the fairing is constructed of a foam-aluminum composite comprising: a first aluminum sheet, a second aluminum sheet, and polyethylene foam disposed therebetween.

24. The fluid-drag reduction system of Claim 1, wherein the fluid-drag reduction system is an autonomous fluid-drag reduction system.

25. The fluid-drag reduction system of Claim 1, wherein the fluid-drag reduction system is a semi -autonomous fluid-drag reduction system.

26. A method comprising: receiving, from a GPS transceiver, position data associated with a current location and a timestamp associated with the position data; and determining, using one or more processors, a speed based on the position data, the timestamp, previous position data, and previous timestamp; determining, using the one or more processors, whether the speed is greater than a user-configurable threshold; and in response to determining that the speed is greater than the user-configurable threshold, transmitting, to an actuator, a signal indicating the actuator to deploy a fluid- drag reduction system.

27. The method of Claim 26, further comprising: receiving, from a position sensor, a signal indicating the fluid-drag reduction system is in a fully deployed configuration; and transmitting, to the actuator, a signal that indicates the actuator to halt deployment of the fluid-drag reduction system.

28. The method of Claim 26, further comprising: receiving, from a position sensor, a signal indicating the fluid-drag reduction system is in a fully retracted configuration; and transmitting, to the actuator, a signal that indicates the actuator to halt retraction of the fluid-drag reduction system.

29. The method of Claim 26, further comprising: receiving, over a network, a user- configurable threshold.

30. The method of Claim 26, further comprising: streaming, over a network, a map navigation data comprising at least one of: a compass heading, map data comprising transit data, a destination location, a departure location, or traffic data.

31. The method of Claim 26, further comprising: determining that the speed is not greater than the user-configurable threshold: transmitting, to an actuator, a signal indicating the actuator to retract the fluid- drag reduction system.

32. The method of Claim 26, further comprising: determining that the speed is not greater than the user-configurable threshold: determining that the vehicle’s hazard lights are activated; and transmitting, to an actuator, a signal indicating the actuator to retract the fluid-drag reduction system.

33. The method of Claim 26, in response to determining that the speed is not greater than the user-configurable threshold: determining that the current position is within a predetermined radius of a destination location; and transmitting, to an actuator, a signal indicating the actuator to retract the fluid- drag reduction system.

34. The method of Claim 26, wherein deploying the fluid-drag reduction system comprises transitioning the fluid-drag reduction system from a fully retracted configuration to a fully deployed configuration; and wherein retracting the fluid-drag reduction system comprises transitioning the fluid- drag reduction system from the fully deployed configuration to the fully retracted configuration.

35. A method comprising: receiving position data associated with a current location and a timestamp associated with the position data, a destination location, a departure location, data indicative of a predetermined area associated with the destination location, and data indicative of a predetermined area associated with the departure location; determining, based on the position data, whether the current location is within the predetermined area associated with the destination location; and in response to determining that the current location is within the predetermined area associated with the destination location: transmitting, to an actuator, a signal indicating the actuator to retract a fluid- drag reduction system; in response to determining that the current location is not within the predetermined area associated with the destination location: determining whether the current location is within the predetermined area associated with the departure location; and in response to determining that the current location is within the predetermined area associated with the departure location: transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system; in response to determining that the current location is not within the predetermined area associated with the departure location; and transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system.

36. The method of Claim 35, further comprising: receiving, from a GPS transceiver, the position data associated with the current location and the timestamp associated with the position data; and receiving, from a server via a network, the destination location, the departure location, the data indicative of a predetermined area associated with the destination location, and the data indicative of a predetermined area associated with the departure location.

37. The method of Claim 35, further comprising: receiving, at a user interface, a first user input indicative of the position data associated with a current location and the timestamp associated with the position data; receiving, at the user interface, a second user input indicative of a destination location, and a third user input indicative of a departure location; and generating, using one or more processors, data indicative of a predetermined area associated with the departure location, and data indicative of a predetermined area associated with the destination location.

38. A method comprising: receiving, via a network or an on-board sensor, hyper-local weather data associated with a predetermined area around a current location, position data associated with the current location, a timestamp associated with the position data, a destination location, a departure location, data indicative of a predetermined area associated with the destination location, and data indicative of a predetermined area associated with the departure location; determining, based on the position data, whether the current location is within the predetermined area associated with the destination location; and in response to determining that the current location is located within the predetermined area associated with the destination location: transmitting, to an actuator, a signal indicating the actuator to retract a fluid- drag reduction system; in response to determining that the current location is not located within the predetermined area associated with the destination location: determining whether the current location is within the predetermined area associated with the departure location; and in response to determining that the current location is located within the predetermined area associated with the departure location: transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system; in response to determining that the current location is not within the predetermined area associated with the departure location: determining, based on the hyper-local weather data, whether a fluid-drag reduction system’s safe operation limits will be exceeded; in response to determining that the fluid-drag reduction system’s safe operation limits will be exceeded: transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system; in response to determining that the fluid-drag reduction system’s safe operation limits will not be exceeded: transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system.

39. The method of Claim 38, wherein the hyper-local weather data comprises at least one of: current wind speed, current wind speed direction, current wind gust, current wind gust direction, current precipitation category, current precipitation rate, average wind speed, average wind speed direction, average wind gust, average wind gust direction, average precipitation category, average precipitation rate, historical wind speed, historical wind speed direction, historical wind gust, historical wind gust direction, historical precipitation category, historical precipitation rate, forecasted wind speed, forecasted wind speed direction, forecasted wind gust, forecasted wind gust direction, forecasted precipitation category, or forecasted precipitation rate.

40. The method of Claim 38, wherein determining, based on the hyper-local weather data, whether the fluid-drag reduction system’s safe operation limits will be exceeded further comprises: calculating a wind speed perpendicular to the vehicle’s direction of travel or a wind gust perpendicular to the vehicle’s direction of travel; interpolating a coefficient of friction (CoF) based on the hyper-local weather data; determining, based on vehicle properties and the interpolated CoF, a wind speed threshold or a wind gust threshold above which operation of the fluid-drag reduction system in a fully deployed configuration is unsafe; determining, based on the hyper-local weather data, an excessive wind gust probability of a wind gust exceeding the wind gust threshold or an excessive wind speed probability of a wind speed exceeding the wind speed threshold; determining whether the excessive wind gust probability or the excessive wind speed probability exceed a user-configurable threshold above which the probability of the vehicle encountering wind speeds or wind gusts is considered unsafe to operate the fluid-drag reduction system in the fully deployed configuration; and in response to determining that the excessive wind gust probability or the excessive wind speed probability exceed a user-configurable threshold; transmitting, to the actuator, a signal indicating the actuator to retract the fluid-drag reduction system; in response to determining that the excessive wind gust probability or the excessive wind speed probability does not exceed a user-configurable threshold; and transmitting, to the actuator, a signal indicating the actuator to deploy the fluid-drag reduction system.

41. The method of Claim 40, wherein the vehicle properties comprises at least one of: a table of tire coefficients of frictions, vehicle weight, vehicle weight distribution, vehicle dimensions, vehicle surface area, number of axles, damping coefficients for the vehicle’s suspension system, and table-tilt alpha value.

42. A method comprising: receiving, from a first relay in communication with a microcontroller and a first indication light of a vehicle, a signal indicating an active state of the first relay; receiving, from a second relay in communication with the microcontroller and a second indication light of the vehicle, a signal indicating an active state of the second relay; determining that the active states of the first relay and the second relay are received synchronously; and transmitting, to an actuator, a signal to retract a fluid-drag reduction system.

43. The method of Claim 42, wherein the first indication light is at least one of: a first turn light or a first reverse light; and wherein the second indication light is at least one of: a second reverse light or a second turn light.

44. The method of Claim 42, further comprising: receiving, from a position sensor in communication with the microcontroller, a signal indicating the fluid-drag reduction system is in a fully retracted configuration; and transmitting, to the actuator, a signal that indicates to the actuator to halt retraction of the fluid-drag reduction system.

45. The method of Claim 42, wherein the first relay is wired in a parallel configuration with the first indication light.