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[[File:Quantum refrigerator at UCL (17626619658).jpg|thumb|right|upright|One of the Chandelier's dilution refrigerators to cool down the quantum processors. The chandelier shape of the refrigerators is how the project got its name.]]
[[File:Quantum refrigerator at UCL (17626619658).jpg|thumb|right|upright|One of the Chandelier's dilution refrigerators to cool down the quantum processors. The chandelier shape of the refrigerators is how the project got its name.]]


Project Chandelier is a [[Janpia|Janpian]] Quantum Computer, currently in development by the D-Arithmos Systems Workers' Union, with special support from the [[Ministry of Industrial Development]]. The aim of the project is to create a computer capable of directing and controlling the Party's overall economic planning, as well as to develop other synergetic systems to replace certain computers that uses traditional sorting algorithms or computational time complexity. As commonly found in quantum computers, the Project Chandelier employs qubits, which utilizes superposition to make both 1 and 0 exist simultaneously, as compared to bits which can only exist in separate 1 and 0 states.
Project Chandelier is a [[Janpia|Janpian]] Quantum Computer, currently in development by the D-Arithmos Systems Workers' Union, with special support from the [[Ministry of Industrial Development]]. The aim of the project is to create a computer capable of directing and controlling the Party's overall economic planning, as well as to develop other synergetic systems to replace certain computers that utilize traditional sorting algorithms or rely on certain aspects of computational time complexity. As commonly found in quantum computers, Project Chandelier employs qubits, which utilize superposition to make a superposition of 1 and 0 possible, as compared to bits which can only exist in separate 1 and 0 states.


According to the D-Arithmos Systems Union, Project Chandelier will be capable of assisting the Party's space development endeavors, given that the computer has a faster recall rates for the spacecraft's instruction database. Additionally, the union has also claimed that this will assist in the rapid decryption of public keys, reducing the necessary time from months or weeks to just a few hours, making it potentially beneficial to the Party's cybersecurity measures. The Union has also promised other opportunities in physics and mathematical simulation once the system is operational, although their primary goal as it currently stands is on the economic implications of the system, including the capacity for automated economic decision making.
According to the D-Arithmos Systems Union, Project Chandelier will be capable of assisting the Party's space development projects, owing to the capacity of the computer to recall information within spacecraft instructional databases in a quicker fashion than conventionally possible. Additional claims by the Union are that this will assist in the rapid decryption of public keys, reducing the necessary time for this process from weeks to hours, which it believes could have potential benefits for encryption in Janpia and cybersecurity measures as a whole. The Union has also promised other opportunities in physics and mathematical simulation once the system is operational, although their primary goal as it currently stands is on the economic implications of the system, including the capacity for automated economic decision making.


==Origins==
==Origins==


Prior to Project Chandelier, the activities of D-Arithmos Systems Workers' Union was primarily focused on participating in artificial intelligence conventions, organizing programmer meet-ups, offering programming solutions, and conducting theoretical scientific computer studies involving quantum physics. In 2014, Urescha Toromii was elected as the Representative of their Workers' Council. Prior to the election, Urescha was a prominent computer programmer, and was the head of the union's study on the computational quantum simulations theorem, as well as quantum machine learning. He is quite interested on the development of a faster computer that requires less complex big-O notation, and was inspired by the algorithmic complexities of SACHI, an artificial system that governs [[Darlingtown]].
Before Project Chandelier, the D-Arithmos Systems Union was primarily focused on the development of artificial intelligence, including participation in conventions relating to such, organization of programmer meetings, provision of programming solutions relating to such, and the beginning of work on theoretical studies relating to the role of computers involving quantum physics. In 2014, Urescha Toromii was elected as the representative of their Workers' Council, coming to prominence before such as a notable programmer and the head of the union's study on the computational quantum simulations theorem, additionally working on quantum machine learning. His primary interest is in the development of computers requiring less utilization of big-O notation, a change which would be a boon to the speed of said computers, with these efforts being inspired by the design of SACHI, the artifical system governing [[Darlingtown]].


Under his leadership, Urescha has pivotted the union’s focus from theoretical studies to practical applications, specifically towards the development of quantum computers. His vision was to develop a system capable of surpassing SACHI's performance, with a larger database and more extensive information processing, ultimately aiming to create a computer that could manage the entire Party and its functions, moving toward algorithmic governance.
Under Urescha's leadership, the union's focus has pivoted from theoretical studies to the implementation of practical applications for quantum computing technology, including the development of an functioning quantum computer. The primary cited vision for this plan was the development of a system which could surpass SACHI, utilizing superior database storage and information processing technologies to create a system which could manage the functions of the Party in a direct fashion, in what he has called "Algorithmic Governance".
In 2015, the first operational Janpian quantum processor was developed by the union known as the DASQ-1 (Dusk-1), a 6 qubit photonic quantum processor, utilized to process the database of the Kalingrad Medical Institute. At that time, the DASQ-1 was a huge leap as compared to normal 6 bits processors, which is capable of processing 64 binary states, albeit in a singular period of time. This is mainly due to how bits can only represent one data at a time, that being 1 or 0, while a qubit can represent both states of it given the idea of superposition. This represents a notable advancement in comparison to 6-bit processing systems in current utilization, which would be forced to individually process each state, allowing a quantum system using this processor to be quicker in a variety of ways than regular systems.
In 2015 the first operational Janpian quantum processor was developed by the union, this initial system being known as DASQ-1 (Dusk-1), a 6 qubit photonic quantum processor, utilized for the purposes of processing the database of the Kalingrad Medical Institute. At that time, the DASQ-1 presented a notable advancement in comparison to normal 6 bit processors, which were only capable of processing 64 binary states sequentially owing to the nature of how regulars computers process data. A qbit, as used by the DASQ-1 would allow for the ability to process these binary states simultaneously due to the nature of superposition, meaning it is able operate in a more efficient manner in comparison to traditional systems and thus that it is able to more quickly accomplish key functions.


The DASQ-1's public release processor would garner notable media, and scientific, attention, as well as Party and governmental attention - with the state, most especially the Ministry of Industrial Development, beginning to provide support for the development of quantum compute systems. More specifically, the MID would offer a contract to develop means to replace the necessity of the Ministry of Economics and Trade, with the MID providing the necessary funding, resources, and manpower in exchange for a guarantee that such a system would be developed in under 50 years.
The public release of the DASQ-1 processor would garner notable media, scientific, and Party attention - with the latter, most especially the Ministry of Industrial Development, beginning to provide support for the development of quantum compute systems. More specifically, the MID would offer a contract to develop means to replace the necessity of the Ministry of Economics and Trade, with the MID providing the necessary funding, resources, and manpower in exchange for a guarantee that such a system would be developed in under 50 years.


This agreement was signed in August 2016, with the official beginning of the project following swiftly. The new system would initially be named the DASQ-2, but due to the hanging of dilution refrigerators on the ceiling for cooling purposes, it would garner the unofficial (and eventually officially adopted) name of Chandelier.
This agreement was signed in August 2016, with the official beginning of the project following swiftly. The new system would initially be named the DASQ-2, but due to the hanging of dilution refrigerators on the ceiling for cooling purposes, it would garner the unofficial (and eventually officially adopted) name of Chandelier.


==Design==
==Design==
As inherent to the agreement, the Workers' Union of D-Arithmos began working on a project which uses a new form of quantum processors as a computer system, which is aimed to be modular and scalable for future developments. The design will be Circuit-Based and will still use the traditional logic gates to compute and function.
As inherent to the agreement, D-Arithmos would begin development of a project which could utilize the a new form quantum processor for economic and mathematic planning purposes in a modular, scalable format. It has been determined that maintaining a system of circuit-based development and traditional utilization of logic gates for computing and functioning purposes is the most effective means of creating a viable product, excluding the inherent differences in the logic gates required by the capacity for the superpositioning of 1 and 0.  


The dilution refrigeration system which the project received its name from creates and maintains a sub-zero temperature environment, with an average temperature of -273.1415 Celsius, or -459.6547 Fahrenheit. This system was developed by the internal cytotechnology department of D-Arithmos, with support from the Ministry of Industrial Development. (TBA)
The dilution refrigeration system which the project received its name from creates and maintains a sub-zero temperature environment, with an average temperature of -273.1415 Celsius, or -459.6547 Fahrenheit. This system was developed by the internal cytotechnology department of D-Arithmos, with support from the Ministry of Industrial Development. (TBA)

Latest revision as of 12:19, 5 November 2024

One of the Chandelier's dilution refrigerators to cool down the quantum processors. The chandelier shape of the refrigerators is how the project got its name.

Project Chandelier is a Janpian Quantum Computer, currently in development by the D-Arithmos Systems Workers' Union, with special support from the Ministry of Industrial Development. The aim of the project is to create a computer capable of directing and controlling the Party's overall economic planning, as well as to develop other synergetic systems to replace certain computers that utilize traditional sorting algorithms or rely on certain aspects of computational time complexity. As commonly found in quantum computers, Project Chandelier employs qubits, which utilize superposition to make a superposition of 1 and 0 possible, as compared to bits which can only exist in separate 1 and 0 states.

According to the D-Arithmos Systems Union, Project Chandelier will be capable of assisting the Party's space development projects, owing to the capacity of the computer to recall information within spacecraft instructional databases in a quicker fashion than conventionally possible. Additional claims by the Union are that this will assist in the rapid decryption of public keys, reducing the necessary time for this process from weeks to hours, which it believes could have potential benefits for encryption in Janpia and cybersecurity measures as a whole. The Union has also promised other opportunities in physics and mathematical simulation once the system is operational, although their primary goal as it currently stands is on the economic implications of the system, including the capacity for automated economic decision making.

Origins

Before Project Chandelier, the D-Arithmos Systems Union was primarily focused on the development of artificial intelligence, including participation in conventions relating to such, organization of programmer meetings, provision of programming solutions relating to such, and the beginning of work on theoretical studies relating to the role of computers involving quantum physics. In 2014, Urescha Toromii was elected as the representative of their Workers' Council, coming to prominence before such as a notable programmer and the head of the union's study on the computational quantum simulations theorem, additionally working on quantum machine learning. His primary interest is in the development of computers requiring less utilization of big-O notation, a change which would be a boon to the speed of said computers, with these efforts being inspired by the design of SACHI, the artifical system governing Darlingtown.

Under Urescha's leadership, the union's focus has pivoted from theoretical studies to the implementation of practical applications for quantum computing technology, including the development of an functioning quantum computer. The primary cited vision for this plan was the development of a system which could surpass SACHI, utilizing superior database storage and information processing technologies to create a system which could manage the functions of the Party in a direct fashion, in what he has called "Algorithmic Governance".

In 2015 the first operational Janpian quantum processor was developed by the union, this initial system being known as DASQ-1 (Dusk-1), a 6 qubit photonic quantum processor, utilized for the purposes of processing the database of the Kalingrad Medical Institute. At that time, the DASQ-1 presented a notable advancement in comparison to normal 6 bit processors, which were only capable of processing 64 binary states sequentially owing to the nature of how regulars computers process data. A qbit, as used by the DASQ-1 would allow for the ability to process these binary states simultaneously due to the nature of superposition, meaning it is able operate in a more efficient manner in comparison to traditional systems and thus that it is able to more quickly accomplish key functions.

The public release of the DASQ-1 processor would garner notable media, scientific, and Party attention - with the latter, most especially the Ministry of Industrial Development, beginning to provide support for the development of quantum compute systems. More specifically, the MID would offer a contract to develop means to replace the necessity of the Ministry of Economics and Trade, with the MID providing the necessary funding, resources, and manpower in exchange for a guarantee that such a system would be developed in under 50 years.

This agreement was signed in August 2016, with the official beginning of the project following swiftly. The new system would initially be named the DASQ-2, but due to the hanging of dilution refrigerators on the ceiling for cooling purposes, it would garner the unofficial (and eventually officially adopted) name of Chandelier.

Design

As inherent to the agreement, D-Arithmos would begin development of a project which could utilize the a new form quantum processor for economic and mathematic planning purposes in a modular, scalable format. It has been determined that maintaining a system of circuit-based development and traditional utilization of logic gates for computing and functioning purposes is the most effective means of creating a viable product, excluding the inherent differences in the logic gates required by the capacity for the superpositioning of 1 and 0.

The dilution refrigeration system which the project received its name from creates and maintains a sub-zero temperature environment, with an average temperature of -273.1415 Celsius, or -459.6547 Fahrenheit. This system was developed by the internal cytotechnology department of D-Arithmos, with support from the Ministry of Industrial Development. (TBA)

See also