Eric Teller

20130325241, Dec 5, 2013

Jun 1, 2012

13/486886

Peter Lombrozo - Santa Cruz CA, US
Eric Teller - San Francisco CA, US
Bradley Templeton - Sunnyvale CA, US

GOOGLE INC. - Mountain View CA

G05D 1/00

701 23

A vehicle configured to operate in an autonomous mode can obtain sensor data from one or more sensors observing one or more aspects of an environment of the vehicle. At least one aspect of the environment of the vehicle that is not observed by the one or more sensors could be inferred based on the sensor data. The vehicle could be controlled in the autonomous mode based on the at least one inferred aspect of the environment of the vehicle.

20230034563, Feb 2, 2023

Jun 27, 2022

17/850732

- Mountain View CA, US
Andrè Prager - Sunnyvale CA, US
Eric Teller - Palo Alto CA, US

B64F 1/36
G06Q 10/08
H02J 7/00

Methods and systems for recipient-assisted recharging during delivery by an unmanned aerial vehicle (UAV) are disclosed herein. During a UAV transport task, a UAV determines that the UAV has arrived at a delivery location specified by a first flight leg of the transport task. The UAV responsively initiates a notification process indicating that a recipient-assisted recharging process should be initiated at or near the delivery location. When the UAV determines that the recipient-assisted recharging process has recharged a battery of the UAV to a target level, and also determines that a non-returnable portion of the payload has been removed from the UAV while a returnable portion of the payload is coupled to or held by the UAV, the UAV initiates a second flight segment of the transport task.

20200278702, Sep 3, 2020

May 12, 2020

15/930054

- Mountain View CA, US
James Schmalzried - San Jose CA, US
Scott Velez - Mountain View CA, US
Andre Prager - Sunnyvale CA, US
Eric Teller - Palo Alto CA, US
Matthew Nubbe - Santa Clara CA, US

G05D 1/10
B64C 39/02
G05D 1/00
G06Q 50/30
G06Q 10/06
G06Q 10/08

An example method involves determining an expected demand level for a first type of a plurality of types of transport tasks for unmanned aerial vehicles (UAVs), the first type of transport tasks associated with a first payload type. Each of the UAVs is physically reconfigurable between at least a first and a second configuration corresponding to the first payload type and a second payload type, respectively. The method also involves determining based on the expected demand level for the first type of transport tasks, (i) a first number of UAVs having the first configuration and (ii) a second number of UAVs having the second configuration. The method further involves, at or near a time corresponding to the expected demand level, providing one or more UAVs to perform the transport tasks, including at least the first number of UAVs.

20190196512, Jun 27, 2019

Dec 21, 2017

15/851693

- Mountain View CA, US
James Schmalzried - San Jose CA, US
Scott Velez - Mountain View CA, US
Andre Prager - Sunnyvale CA, US
Eric Teller - Palo Alto CA, US
Matthew Nubbe - Santa Clara CA, US

G05D 1/10
B64C 39/02
G05D 1/00
G06Q 10/06
G06Q 50/30

An example method involves determining an expected demand level for a first type of a plurality of types of transport tasks for unmanned aerial vehicles (UAVs), the first type of transport tasks associated with a first payload type. Each of the UAVs is physically reconfigurable between at least a first and a second configuration corresponding to the first payload type and a second payload type, respectively. The method also involves determining based on the expected demand level for the first type of transport tasks, (i) a first number of UAVs having the first configuration and (ii) a second number of UAVs having the second configuration. The method further involves, at or near a time corresponding to the expected demand level, providing one or more UAVs to perform the transport tasks, including at least the first number of UAVs.

20190197463, Jun 27, 2019

Dec 22, 2017

15/852804

- Mountain View CA, US
André Prager - Sunnyvale CA, US
Eric Teller - Palo Alto CA, US

G06Q 10/08

Methods and systems for recipient-assisted recharging during delivery by an unmanned aerial vehicle (UAV) are disclosed herein. During a UAV transport task, a UAV determines that the UAV has arrived at a delivery location specified by a first flight leg of the transport task. The UAV responsively initiates a notification process indicating that a recipient-assisted recharging process should be initiated at or near the delivery location. When the UAV determines that the recipient-assisted recharging process has recharged a battery of the UAV to a target level, and also determines that a non-returnable portion of the payload has been removed from the UAV while a returnable portion of the payload is coupled to or held by the UAV, the UAV initiates a second flight segment of the transport task.

20190185149, Jun 20, 2019

Dec 20, 2017

15/849365

- Mountain View CA, US
Adam Woodworth - San Jose CA, US
Eric Teller - Palo Alto CA, US
Jacob Huffman - Cupertino CA, US
Martin Kubie - San Francisco CA, US

B64C 27/00
B64C 39/02
B64C 27/14
B64D 31/00
G10K 11/178

A technique of controlling tonal noises produced by an unmanned aerial vehicle (UAV) includes generating thrust with a plurality of rotor units mounted to the UAV to propel the UAV into flight. Each of the rotor units includes a bladed rotor. A rotation rate or a phase delay of at least one of the rotor units is adjusted relative to another of the rotor units. The adjustment causes a spread in the tonal noises generated by the rotor units.

20160154085, Jun 2, 2016

Feb 9, 2016

15/019772

- Mountain View CA, US
Waleed KADOUS - Santa Clara CA, US
Eric Teller - Palo Alto CA, US
Cliff Biffle - Berkeley CA, US
Edward Allen Keyes - Mountain View CA, US

G01S 5/04
G01S 19/24
G01S 5/02
G01S 19/03
G01S 1/04

Disclosed herein are embodiments of a balloon-based positioning system and method. In one example embodiment, a system includes at least three balloons, with each balloon including a position-determining module (PDM) and a position-broadcasting module (PBM). Each PDM is configured for determining a position of the respective balloon and each PBM is configured for broadcasting a balloon signal containing balloon-positioning data of the respective balloon. The balloon-positioning data includes the determined position of the respective balloon and a corresponding time of broadcast.