# GOSat > 33492 **Wikidata**: [Q111496929](https://www.wikidata.org/wiki/Q111496929) **Source**: https://4ort.xyz/entity/gosat ## Summary GOSat is an artificial satellite identified by the numeric descriptor 33492. It is a human-made object placed into orbit, classifying it as a specialized type of spacecraft designed to operate in space. ## Key Facts - **Identifier**: 33492 - **Classification**: Artificial satellite (subclass of spacecraft). - **Entity Code**: `Entity["Satellite", "33492"]` (Wolfram Language). - **Definition**: A human-made object put into an orbit around a celestial body. - **Primary Functions**: Capable of supporting communication, navigation, scientific research, and military applications. ## FAQs ### Q: What is GOSat? GOSat is an artificial satellite identified by the code 33492. It is a human-made spacecraft placed into orbit. ### Q: How is GOSat classified? GOSat is classified as an artificial satellite, which is a specific subclass of spacecraft engineered to orbit a celestial body. ### Q: What distinguishes an artificial satellite like GOSat from other spacecraft? While "spacecraft" is a broad category that includes probes and crewed vehicles, an artificial satellite like GOSat is specifically designed to maintain orbit around a celestial body such as Earth. ### Q: What are the orbital characteristics of artificial satellites? Depending on its specific mission design, a satellite like GOSat may operate in geostationary orbit (fixed over a point on Earth), low Earth orbit (LEO), or a heliocentric orbit (around the Sun). ## Why It Matters As an artificial satellite, GOSat represents a technology that has revolutionized global infrastructure. Satellites are the backbone of modern communication, navigation, and scientific observation. They enable real-time weather monitoring, global positioning systems (GPS), and internet connectivity. The deployment of satellites addresses critical needs in military defense and environmental monitoring. Furthermore, the category of artificial satellites sparked the Space Age with the launch of Sputnik 1 in 1957 and continues to drive advancements in aerospace technology, though the field now faces challenges regarding space debris and orbital congestion that require sustainable management solutions. ## Notable For - **Classification**: Instance of an artificial satellite (human-made orbital object). - **Technological Lineage**: Belongs to the class of spacecraft that began with Sputnik 1 in 1957. - **Capability Scope**: Part of a category capable of diverse functions, from passive signal reflection to complex orbital power generation. - **Data Representation**: Uniquely identified in knowledge systems by the ID 33492. ## Body ### Identification and Classification GOSat is explicitly defined as an **artificial satellite**, a classification denoting a human-made object put into an orbit. In structured knowledge bases, it is associated with the identifier **33492** and is represented in the Wolfram Language as `Entity["Satellite", "33492"]`. ### Definition of Artificial Satellite As a member of this class, GOSat falls under the definition of a machine placed into orbit around a celestial body, typically Earth. This distinguishes it from other spacecraft like probes or crewed vehicles. The category includes various specialized types: - **Passive satellites**: Objects like Project Echo that reflect signals. - **Tethered satellites**: Systems connected by cables. - **Miniaturized variants**: Includes femtosatellites and picosatellites. - **Orbital power plants**: Satellites designed to capture and wirelessly transmit solar energy. ### Operational Context Artificial satellites operate within specific orbital regimes: - **Geostationary**: Remaining fixed over a specific point on Earth. - **Low Earth Orbit (LEO)**: Commonly used for communication and Earth observation. - **Heliocentric**: Orbits centered around the Sun. ### Historical and Functional Background The class of artificial satellites to which GOSat belongs was established in 1957 with the Soviet Union's launch of Sputnik 1. Since then, these objects have become indispensable for: - **Communication**: Enabling television, internet, and telephony. - **Navigation**: Powering GPS constellations. - **Military applications**: Providing secure communications (e.g., Syracuse 4, Gonets-M). - **Scientific research**: Facilitating geodetic measurements (e.g., PAGEOS) and environmental monitoring. ### Challenges and Sustainability The operation of artificial satellites occurs within an environment facing challenges such as space debris and orbital congestion. Defunct satellites and fragments pose collision risks, leading to the development of space debris removal satellites to ensure the sustainability of orbital paths.