Robot Terms Explained: A-Z Glossary for Beginners

Robot terms A through E

A

Actuator: The “muscle” of the robot. It converts control signals into movement, rotating, lifting, or pushing components into action. Powered by electric motors, hydraulics, or pneumatics.

Adaptive Control: A type of control system that allows robots to modify their behavior in real time based on environmental feedback. Useful for unpredictable or dynamic tasks.

Aerobot: An aerial robot capable of flying autonomously, often used in environmental monitoring, surveillance, or drone-based delivery systems.

Algorithm: A set of programmed rules or instructions that a robot follows to make decisions or carry out tasks. Algorithms are the core of robot intelligence and movement planning.

Android: A humanoid robot designed to resemble an adult human male. The ‘andro’ prefix is in reference to the assigned masculine gender of the machine.

Articulated manipulator: A robot arm with multiple joints (like a human shoulder, elbow, wrist) that allows it to move in several directions. Common in manufacturing and welding lines.

Automaton: A mechanically driven device that mimics life or performs repetitive tasks. Popular in ancient engineering, some even powered by water or clockwork.

Autonomous vehicle: A self-driving robot (car, drone, rover) that navigates and makes decisions without human control, using sensors, GPS, and onboard AI.

Axis/degree of freedom: Describes how many directions or rotations a robot can move in. A typical robotic arm might have 6 degrees of freedom, allowing for complex, lifelike motion.

B

Battery Management System (BMS): Software and hardware that monitor and manage a robot’s battery performance, preventing overheating or overcharging.

Bionics: The integration of biological principles into robotics, like mimicking how muscles work or how insects walk to improve robot design.

C

function of a cartesian robotic art, courtesy of toshiba.com

Cartesian manipulator: A robot that moves in straight lines along the X, Y, and Z axes. Think 3D printers or CNC machines, precise, linear, and ideal for pick-and-place tasks.

Central processing unit: The robot’s “brain.” It interprets signals from sensors and controls actions across the system.

Chassis: The structural frame or base of a robot on which components like actuators, sensors, and processors are mounted.

Cloud robotics: Robots that rely on cloud computing to process data or coordinate behavior, ideal for fleets of connected bots or lightweight designs.

Robotics terms F through K

F

Feedback sensor: Provides real-time environmental or mechanical data to the robot, helping it adjust movements or decisions dynamically.

Different variants of robot sensors (source: http://iggyclass.blogspot.com)

Force limiting: A safety feature that caps how fast or hard a robot can move, preventing injury during human interaction.

Force Sensor: Measures pressure or force exerted by the robot, useful for fragile tasks like assembling electronics or pouring drinks.

G

Gantry: A large, overhead support structure that lets a robot move along fixed rails. Often used for high-precision or heavy-duty industrial robots.

Gynoid: A female-presenting humanoid robot. The counterpart to androids, typically used in research or media portrayals of robotics.

Example of a feminized robot from the video game Starcraft II

H

Haptic: Touch-based feedback used to give robots sensitivity to surfaces and force. Enables delicate tasks like handling glass or medical tools.

Harness: Wiring and cables bundled together to deliver power and data throughout a robot.

Hexapod: A six-legged walking robot modeled after insects. Known for stability and adaptability on rough terrain.

Humanoid: Any robot with a body plan similar to a human. Includes both androids and gynoids and used for advanced AI interaction and mobility research.

Hydraulics: Uses pressurized fluid to generate mechanical movement. Common in heavy-load robots or exoskeletons.

I

Industrial robot: Robots purpose-built for manufacturing. Think welding arms, packaging bots, or pick-and-place machines on an assembly line.

Input device: A control or programming interface — joystick, touch panel, keyboard — that allows humans to direct or teach robot behavior.

Robot terms L through Z

L

Laser: Used in robots for measuring distance, guiding cutting paths, or precise welding. Also common in autonomous navigation (LiDAR systems).

N

Nanobot: Microscopic robots (often theoretical or experimental) built at the nanoscale, used in medicine, chemistry, or materials science.

P

Payload: The maximum weight a robot can carry without performance loss. Key factor in selecting robots for lifting or transport tasks.

Pinch Points: Hazardous areas in robot joints where limbs or clothing could be caught. Often marked with warning labels.

Pneumatics: Generates robotic motion using compressed air. Quieter and cleaner than hydraulics, often used in lightweight or delicate bots.

Powered Exoskeleton: Wearable robotics designed to enhance human strength or mobility. Used in rehabilitation, military, and industrial lifting.

The mech is a sci-fi staple and dramatic example of what exoskeletons could one day be

Prosthetic: A robotic or programmable limb replacement. Modern versions include sensor inputs and adaptive motion for amputees.

R

Robot: A machine capable of carrying out tasks independently, based on programmed instructions or environmental feedback.

RPA: Software bots that perform repetitive digital tasks, no physical robot involved. Common in finance, HR, and customer service.

S

Sensor: Devices that let robots “see,” “feel,” or “hear” their environment. Includes cameras, pressure sensors, proximity detectors, and more.

Singularity: A point where a robot’s arm joints align in a way that limits movement. Not to be confused with the AI singularity!

U

Uptime: The opposite of downtime, how long a robot operates without interruption. High uptime is a sign of reliable performance.

Types of robots explained: What are the different kinds?

To make sense of robotics terms, it helps to first understand how robots are categorized. Here’s a breakdown of the most common robot types you’ll encounter:

Industrial robots

These are the backbone of factories worldwide, built for speed, precision, and repetition. Whether it’s welding car frames or assembling smartphones, industrial robots get the job done.

Examples:

• Robotic arms with end effectors
• Cartesian or SCARA robots
• Heavy-load machines for fabrication

Key terms: Actuator, payload, end effector, downtime

Service robots

Service robots work directly with people in homes, offices, and public spaces. They vacuum floors, deliver room service, and even check in hotel guests.

Examples:

• Cleaning bots
• Reception robots
• Home assistants

Key terms: Cobots, haptic, feedback sensor

Autonomous robots

These bots think (a little) for themselves. Using AI, sensors, and software, autonomous robots can navigate environments and adapt to changing inputs, no remote control needed.

Examples:

• Self-driving delivery robots
• Drone swarms
• Warehouse navigation bots

Key terms: Cloud robotics, feedback sensor, intelligent robot

Humanoid robots

Shaped like us, and sometimes eerily lifelike. Humanoid robots include androids (male-formed) and gynoids (female-formed), and they’re often used in AI research and entertainment.

Examples:

• Social robots
• Research androids
• Interactive humanoids in media

Key terms: Android, gynoid, humanoid, articulated manipulator

Robotics vs. Automation: What’s the difference?

These terms get tossed around a lot, sometimes interchangeably, but they mean different things.

Robotics

Robotics is all about physical machines that can move, sense, and act. Robots typically include hardware, software, and actuators to carry out tasks without direct human control.

Automation

Automation refers to the broader concept of making systems run without human intervention. It can be mechanical, software-driven, or involve robots, but doesn’t require them.

RPA vs. Physical robots

Let’s clear up a big point of confusion: RPA has nothing to do with physical robots.

How robots are used in real-world industries

Robots aren’t just sci-fi; they’re reshaping how entire industries work. Here’s where they’re making an impact:

Healthcare

• Surgical robots like Da Vinci systems assist with precision tasks
• Rehab bots help patients regain movement
• Prosthetics offer robotic replacements for limbs

Manufacturing

• Industrial arms handle welding, packaging, and painting
• Cobots assist human workers safely
• Sensors detect product defects in real time

Logistics

• Autonomous mobile robots (AMRs) move goods in warehouses
• Drones conduct inventory or deliver packages
• Cloud coordination allows fleet-wide optimization

Emerging Sectors

• Agriculture: robots monitor soil and harvest crops
• Military: drones and battlefield bots
• Hospitality: room delivery bots and concierge assistants

Frequently asked questions (FAQs) about robotic terms 

Have more questions? Find the answers here. 

Q1. What are the key components of a robot? 

The key components of a robot are sensors, actuators, a control system, power supply, and end effectors. Sensors gather data, actuators move parts, the control system processes input and controls behavior, the power supply provides energy, and end effectors perform specific tasks like gripping or welding.

Q2. What is the difference between robotics and automation? 

The main difference between robotics and automation is that robotics involves machines that can be programmed to perform tasks autonomously, while automation refers to using technology to complete processes with minimal human intervention. Robotics often falls under automation but focuses on flexible, adaptive physical machines.

Q3. How do sensors work in robotics? 

Sensors in robotics work by detecting physical inputs like light, temperature, distance, or motion and converting them into electrical signals. These signals are processed by the robot’s control system to make decisions or adjust behavior. Sensors enable robots to perceive and interact with their environment accurately.

Q4. What are cobots, and how are they used?

Cobots, or collaborative robots, are robots designed to work safely alongside humans. They are used in manufacturing, healthcare, logistics, and assembly lines to assist with tasks like lifting, positioning, or inspecting parts. Cobots enhance productivity by combining human flexibility with robotic precision and consistency. 

Q5. What are the 5 major fields of robotics? 

The 5 major fields of robotics are mechanical engineering, electrical engineering, computer science, control systems, and artificial intelligence. Mechanical engineering designs the robot’s structure, electrical engineering powers and connects components, computer science programs behavior, control systems manage movement, and AI enables perception and decision-making.

The path to knowledge

Now that you understand these commonly searched for robotics terms, you should know everything you need to in order to explore the latest developments in robotics and AI! While you’re at it, take a look at some of the types of robots to get a good sense of what people are talking about in the field today.