Abstract: In one embodiment, a computer-implemented method includes collecting data from at least one component of a micromobility vehicle. The method includes analyzing the data to determine whether a condition of the micromobility vehicle corresponds to an unsafe condition. The method includes determining, based on analysis, that the condition of the micromobility vehicle corresponds to the unsafe condition. The method includes activating an immobilization lock on the micromobility vehicle to immobilize a wheel of the micromobility vehicle responsive to determining that the condition of the micromobility vehicle corresponds to the unsafe condition.

Abstract: In one embodiment, a method of installing a modular micro-mobility fleet vehicle docking system includes: providing multiple base platforms, each including platform interlock feature(s) extending along at least a portion of its perimeter; connecting each base platform to an adjoining one via the associated platform interlock features; providing multiple modular station bodies, each including a vehicle retention system configured to secure a micro-mobility fleet vehicle to the modular station body and a base platform connector disposed at a bottom surface of the modular station body, the base platform connector including a physical locking interface and an electrical connection interface integrated together as a single piece; and securing each modular station body to a corresponding base platform via the associated base platform connector to physically lock the modular station body to the base platform and electrically connect the modular station body to the base platform.

Abstract: A cockpit assembly for a micro-mobility fleet vehicle may include at least two visible and at least partially opposed faces linked by a fold aligned along an axis of a handlebar assembly, such as a first face, a second face, and an intermediate portion connecting the first face to the second face. The first face may include a headlight assembly. The second face may include a display of a user interface that is arranged to face a rider of the fleet vehicle. The display may be disposed adjacent to and/or beneath a mobile device holder. The first face, the second face, and the intermediate portion may wrap at least partially around the handlebar assembly to position the first face towards a front of the fleet vehicle and the second face towards a rear, a rider, and/or a seat of the fleet vehicle.

Abstract: Techniques are disclosed for systems and methods associated with locking a micromobility transit vehicle to a stationary object. A multimodal transportation system may include a docking station including a securement point, and a micromobility transit vehicle securable to the securement point of the docking station. The micromobility transit vehicle may include a storage basket and a lock cable including a first end coupled to the storage basket and a second end. The second end of the lock cable may be securable to the securement point of the docking station to lock the micromobility transit vehicle to the docking station. The storage basket may include a pin lock. The pin lock may engage a locking pin of the lock cable to lock the micromobility transit vehicle via the lock cable.

Abstract: Techniques related to retroreflective surface layers for micro-mobility transit vehicles are disclosed. A retroreflective surface layer may be formed over at least a portion of a component of a micro-mobility transit vehicle by forming a powder coat layer over the portion of the component and baking the powder coat layer to cure the powder coat layer. An uncured clear coat layer may be formed over the powder coat layer. The uncured clear coat layer may be impregnated with a plurality of glass beads via an air-pressure applicator. The uncured clear coat layer impregnated with the glass beads may be baked to cure the clear coat layer. The retroreflective surface layer may include the powder coat layer, clear coat layer, and the plurality of glass beads distributed within the clear coat layer. The retroreflective surface layer may reflect incident light back to its source with minimal scattering of the light.

Abstract: Techniques are disclosed for systems and methods to provide modular docking systems and rebalancing systems for micro-mobility fleet vehicles. A modular micro-mobility fleet vehicle docking system includes a base platform including a modular station body receptacle disposed on a top surface of the base platform and a modular station body including a vehicle retention system configured to secure a micro-mobility fleet vehicle to the modular station body. The modular station body includes a base platform interface disposed at a bottom surface of the modular station body that is configured to be physically secured to the base platform by the modular station body receptacle. The modular station body receptacle includes a station locking interface configured to releasably secure the modular station body to the base platform and/or an electrical interface configured to provide power to the modular station body.

Abstract: Systems and methods related to docking stations for accommodating multiple types of micromobility vehicles, for interacting with different users, and for operating securely under low-power constraints are disclosed. A low-power docking station may include a housing having walls defining a vehicle opening, and a latching receiver to engage with a latching mount of the micromobility vehicle when it is positioned in the vehicle opening. The docking station can further include a movable hook having a retention feature and a movable latch having a latching protrusion and a receiving feature. The receiving feature can be configured to receive the latching mount when the latching mount is advanced into the receiving feature, and in response to the receiving feature receiving the latching mount, the movable latch can move such that the latching protrusion of the movable latch is retained by the retention feature of the movable hook.

Abstract: Techniques are disclosed for systems and methods associated with locking a micromobility transit vehicle to a stationary object. A multimodal transportation system may include a docking station including a securement point, and a micromobility transit vehicle securable to the securement point of the docking station. The micromobility transit vehicle may include a storage basket and a lock cable including a first end coupled to the storage basket and a second end. The second end of the lock cable may be securable to the securement point of the docking station to lock the micromobility transit vehicle to the docking station. The storage basket may include a pin lock. The pin lock may engage a locking pin of the lock cable to lock the micromobility transit vehicle via the lock cable.

Abstract: Techniques are disclosed for systems and methods associated with locking a micromobility transit vehicle to a stationary object. A multimodal transportation system may include a docking station including a securement point, and a micromobility transit vehicle securable to the securement point of the docking station. The micromobility transit vehicle may include a storage basket and a lock cable including a first end coupled to the storage basket and a second end. The second end of the lock cable may be securable to the securement point of the docking station to lock the micromobility transit vehicle to the docking station. The storage basket may include a pin lock. The pin lock may engage a locking pin of the lock cable to lock the micromobility transit vehicle via the lock cable.

Abstract: A safety apparatus (20) for a battery (80) has a base (22) for a vehicle (10), sensors (31, 32, 33, 34) and an evaluation apparatus (40). Each sensor (31, 32, 33, 34) is designed to generate a sensor signal (35) on a basis of a deformation of the base (22) and to supply the sensor signal to the evaluation apparatus (40). The evaluation apparatus (40) ascertains from the sensor signals (35) both first information about the location of the deformation of the base (22) and second information about the level of the deformation, and uses the first information and the second information as a basis for determining whether a first state (Z1) is present, in which a driving mode can be maintained, or whether a second state (Z2) is present, in which a driving mode can no longer be maintained.

Abstract: Techniques are disclosed for systems and methods associated with locking a micromobility transit vehicle to a stationary object. A multimodal transportation system may include a docking station including a securement point, and a micromobility transit vehicle securable to the securement point of the docking station. The micromobility transit vehicle may include a storage basket and a lock cable including a first end coupled to the storage basket and a second end. The second end of the lock cable may be securable to the securement point of the docking station to lock the micromobility transit vehicle to the docking station. The storage basket may include a pin lock. The pin lock may engage a locking pin of the lock cable to lock the micromobility transit vehicle via the lock cable.

Abstract: Techniques related to retroreflective surface layers for micro-mobility transit vehicles are disclosed. A retroreflective surface layer may be formed over at least a portion of a component of a micro-mobility transit vehicle by forming a powder coat layer over the portion of the component and baking the powder coat layer to cure the powder coat layer. An uncured clear coat layer may be formed over the powder coat layer. The uncured clear coat layer may be impregnated with a plurality of glass beads via an air-pressure applicator. The uncured clear coat layer impregnated with the glass beads may be baked to cure the clear coat layer. The retroreflective surface layer may include the powder coat layer, clear coat layer, and the plurality of glass beads distributed within the clear coat layer. The retroreflective surface layer may reflect incident light back to its source with minimal scattering of the light.

Abstract: A cockpit assembly for a micro-mobility fleet vehicle may include at least two visible and at least partially opposed faces linked by a fold aligned along an axis of a handlebar assembly, such as a first face, a second face, and an intermediate portion connecting the first face to the second face. The first face may include a headlight assembly. The second face may include a display of a user interface that is arranged to face a rider of the fleet vehicle. The display may be disposed adjacent to and/or beneath a mobile device holder. The first face, the second face, and the intermediate portion may wrap at least partially around the handlebar assembly to position the first face towards a front of the fleet vehicle and the second face towards a rear, a rider, and/or a seat of the fleet vehicle.

Abstract: Techniques are disclosed for systems and methods to provide modular docking systems and rebalancing systems for micro-mobility fleet vehicles. A modular micro-mobility fleet vehicle docking system includes a base platform including a modular station body receptacle disposed on a top surface of the base platform and a modular station body including a vehicle retention system configured to secure a micro-mobility fleet vehicle to the modular station body. The modular station body includes a base platform interface disposed at a bottom surface of the modular station body that is configured to be physically secured to the base platform by the modular station body receptacle. The modular station body receptacle includes a station locking interface configured to releasably secure the modular station body to the base platform and/or an electrical interface configured to provide power to the modular station body.

Abstract: A cockpit assembly for a micro-mobility fleet vehicle may include at least two visible and at least partially opposed faces linked by a fold aligned along an axis of a handlebar assembly, such as a first face, a second face, and an intermediate portion connecting the first face to the second face. The first face may include a headlight assembly. The second face may include a display of a user interface that is arranged to face a rider of the fleet vehicle. The display may be disposed adjacent to and/or beneath a mobile device holder. The first face, the second face, and the intermediate portion may wrap at least partially around the handlebar assembly to position the first face towards a front of the fleet vehicle and the second face towards a rear, a rider, and/or a seat of the fleet vehicle.

Abstract: A safety apparatus (20) for a battery (80) has a base (22) for a vehicle (10), sensors (31, 32, 33, 34) and an evaluation apparatus (40). Each sensor (31, 32, 33, 34) is designed to generate a sensor signal (35) on a basis of a deformation of the base (22) and to supply the sensor signal to the evaluation apparatus (40). The evaluation apparatus (40) ascertains from the sensor signals (35) both first information about the location of the deformation of the base (22) and second information about the level of the deformation, and uses the first information and the second information as a basis for determining whether a first state (Z1) is present, in which a driving mode can be maintained, or whether a second state (Z2) is present, in which a driving mode can no longer be maintained.

Abstract: The present disclosure relates to a locking system for a seat arrangement of a motor vehicle, which seat arrangement has an adjustment component which is adjustable manually into at least one locking position, wherein the locking system has a locking mechanism, and wherein the adjustment component is lockable and releasable in the locking position by means of the locking mechanism, wherein the locking mechanism has an actuation drive by means of which the locking mechanism is releasable in a motorized manner, wherein the locking system has a proximity sensor which is triggerable by a predefined operator control event and wherein, by means of the triggering of the proximity sensor, the adjustment component is releasable in a motorized manner via the actuation drive.