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Tesla Optimus (Tesla humanoid) How Make the Tesla Optimus team (Tesla employees), do all of the operations, listed in this document. Infinity 3D Builder API Build 3D Objects - can build anything Builds per likelihood of demographics; material resources availability; extrapolation options (buttons and descriptions of tentative innovative results) to user 3D Physics Simulations Predicted trajectories and courses of action Multiple predicted options Language Model to 3D Builder API to translate language to 3D simulations of the Infinity 3D Builder API In this document, I'm calling it, "NLP to 3D Simulations API". Collaborate (Partnerships, and Acquisitions) Blender Unity3D Research - To be researched to discover which, of all the options, is the best 3D API company. etc. Language Model APIs Research - Find the best fitting NLP APIs companies. Maybe you can buy a license to use one of the NLP. Teams: Software Infinity 3D Builder API 3D Physics Simulations - motion options NLP to 3D Simulations API - interpreting user communications and commands for the Infinity 3D Builder API ASI APIs (see "ASI APIs", below) Teams: Hardware: Robot Engineering Speed - per joint movement motion speed optimization Talk to the engineers to discover how they can team to specialize on tasks (to categorize specialization teams). The more engineers, the better. Motion agility Material strength Micro-chip Micro-chips: examples of possibilities micro-chip #1 - brain: knowledge of communications and thinking micro-chip #2 - mechanical processing of limbs micro-chip #3 - computer software integration for robot-to-computer-interactions and processing These multi-micro-chips robot-anatomy member parts will allow simultaneous multi-functionality of the robot. Example: the robot can think and talk to you while it is uploading data to a computer. the robot can move and process predictions of motions and future courses of behavior, while it is thinking about communications and talking to someone, and controlling its motions (all three of those types of actions can be processed on separate chips, simultaneously) Example: the robot can communicate with someone, and simultaneously predict its motions, and simultaneously communicate with software, wirelessly, to another computer, and compose procedures of tentative future tasks this is separate from bodily motion behavior, because immediate bodily motion behavior can calculate immediate simulations of vicinity events; meanwhile, the other micro-chip can calculate, simultaneously, future procedures of tasks to be accomplished and 3D simulations of those future bodily behavior courses of action of those procedures; meanwhile, the robot can talk to you; and, meanwhile, the robot can integrate information, wirelessly, to software of a separate computer, from another micro-chip processor ASI APIs This is a separate team of software developers. This team builds per task objective achievement APIs, specialized per tasks to be accomplished. Examples: How the robot will get its information for its task: auto mechanic. How the robot will build 3D simulations of tentative procedures of its future actions. How the robot will get its information for its task: washing dishes. How the robot will get its information for its task: Customer Service Representative at McDonald's restaurant. How the robot will get its information for its task: accounting. How the robot will get its information for its task: FBI agent. How the robot will get its information for its task: Walmart Associate. How the robot will get its information for its task: waiter. How the robot will get its information for its task: registered nurse. Methods for obtaining information for ASI APIs: Surveillance video - translation to 3D simulations of behavior and procedures; plus, coupled 3D simulations of events with document manuals of business operations (cross-examination of predictable events, to create 3D simulations of predicted courses of actions). Setup cameras (which we might call, "observation cameras") in businesses (those which are successful businesses which have trained, experienced employees) for this surveillance purpose. Instructional Videos. Create 3D simulations of behaviors for specific categories of tasks. This might also be done for Language Models, so that the the robot can mimic communication behaviors, expressions, relevant discourse concepts text, and associated jargon. Movies. Create 3D simulations; categorize the simulations for future use. Something about this - important note: The 3D simulations need only be methodical, procedural - script procedures and methods of (1) obtaining data and for (2) concocting data 3D simulations for behavior actions. This means: that the actual videos built do not necessarily need to be retained as electronic documents of recorded robot memory, because the 3D simulation's methods and procedures for the robot to build the 3D simulations in real time, per given situations will be built by these ASI software engineers as "ASI APIs", like so. What the robot won't need is the concocted 3D simulations of predicted events. What the robot will need is access to the source files of the video content (rather, relevant, generic 3D simulations made from these, but not as comprehensive predictions of all behaviors); AND documented manuals of policies and procedures of businesses. Additionally I also need to the Tesla Optimus team to work on engineering the design of a micro-robot-composite humanoid Tesla robot. Purpose: more useful; versatile, transform-able, reconstructable (self-assembling; AND replaceable parts at a small (even micro or, at least, tiny) scale) Gigafactory for building these. Provide these to U.S. citizens (the 150 million human resources of the U.S. nation, currently employed). The robots will pay the company for their own sale price, within 60 months to 3 years, approximately. Government Program The U.S. Government must adopt (acquire) the ASI Humanoids and take control of safety, security and ASI API control and robot ASI API downloads control. Purpose: to prevent humanoid startups from taking over the world (startups, such as Tesla Inc., but Tesla is not the only startup that may soon have the power to takeover the world; once the technology is underway and commercially understood, Joe Doe may also have the power to takeover the world). Research and Development: connections Purpose: All of the below, for the purpose of composing tiny-composite (and micro-composite) robot motion-capable tiny parts making up motion-capable larger parts of the anatomy of the Tesla Optimus humanoid. hydraulic connections (fluid pressure; valve doors (openings which can close upon reaction and syntax commands); fluid inflation; fluid deflation) air and gas pressure connections (inflation; deflation; pressure tension in body parts) electromagnetic connections magnetic connections mechanical touch connections joint connections fitted connections (example - male-to-female ends, e.g. socket and electric wire input to socket (tongue-and-groove)) gear connections; gear-like connections wrap connections suture connections skin elements connections; bone elements connections; etc. - to mimic these types with other material connections Area of interest: rate of speed; rate of change; rate of motion; rate of actions of body parts; rate of motion of tiny-robot-composite parts; rate of agility motions; rate of strength bolster motions Area of interest: self-assembling Area of interest: self-parts-replacing (self-fixing); damage control; longevity; Area of interest: upgrade-able-ready-always; self-assembly-upgrading-able-robot Area of interest: durability Area of interest: agility Area of interest: resource availability don't use(??): screw bolt connections pulley connections reason: because they are not micro-robot or tiny-robot useful options