Letter To The President Of The United States Regarding Mali

“The Er above god”

—————————-

Dear Mr. President,

I am writing to bring your attention to a matter of utmost importance concerning the preservation of an ancient mural depicting the “god”, located in Bamako, the capital city of Mali. This mural, believed to be one of the earliest known artistic representations of a deity in the region, holds immense historical, cultural, and scientific value.

The mural is situated at the following coordinates in Bamako:

god: 16°26'56.87"N 3°40'33.67"W

It is essential that we take immediate action to protect and study this invaluable piece of human history. I strongly urge you to collaborate with the Malian government and relevant international organizations to ensure the mural's preservation and to facilitate comprehensive scientific analysis of the site.

To fully understand the significance of this mural and its context, it is crucial that we gather comprehensive data from the site. This includes precise physical measurements of the mural and its surroundings, as well as the collection of light and lambda wave data. By analyzing the full spectrum of electromagnetic radiation at the site, we may uncover valuable insights into the mural's age, the techniques used in its creation, and the environmental conditions it has endured over the centuries.

Furthermore, I recommend that additional data be collected from two nearby locations:

16°27'2.96"N 3°40'48.73"W
16°27'11.27"N 3°40'56.41"W

Studying these points in relation to the mural site could provide a more comprehensive understanding of the area's historical and geological context.

Mr. President, the preservation and study of this ancient mural is not only a matter of safeguarding Mali's cultural heritage but also an opportunity to expand our knowledge of human history and the development of early religious iconography. By dedicating resources to this endeavor and fostering international collaboration, the United States can demonstrate its commitment to protecting world heritage sites and advancing scientific understanding.

I implore you to take swift action on this matter and to engage with the Malian government and relevant experts to ensure that this priceless piece of human history is preserved for generations to come. The data collected from this site could prove invaluable to researchers across multiple disciplines, including archaeology, anthropology, art history, and physics.

Thank you for your attention to this pressing issue. I am confident that with your support and leadership, we can secure the protection of this ancient mural and unlock the secrets it holds.

Sincerely,

Ramoan Steinway

P.S.

To collect light and lambda wave data and analyze the full spectrum of electromagnetic radiation at the ancient mural site in Bamako, Mali, a variety of sophisticated equipment would be necessary. This equipment would enable researchers to gather comprehensive data about the mural's age, creation techniques, and the environmental conditions it has been exposed to over the centuries.

Spectroradiometer:

This device is used to measure the spectral power distribution of a light source. It can measure the intensity of electromagnetic radiation at different wavelengths, including visible light, ultraviolet (UV), and infrared (IR) regions of the spectrum. A spectroradiometer would help researchers understand the composition of the light reflecting off the mural and its surroundings.

Raman spectrometer:

Raman spectroscopy is a non-destructive technique that uses laser light to analyze the molecular composition of materials. It can identify pigments, binders, and other organic and inorganic compounds used in the mural's creation. This information can provide insights into the age of the mural and the techniques used by the artists.

Portable X-ray fluorescence (pXRF) spectrometer:

This handheld device uses X-ray fluorescence to determine the elemental composition of materials. It can identify the chemical elements present in the mural's pigments, which can help date the artwork and understand the resources available to the artists at the time of its creation.

Multispectral and hyperspectral imaging cameras:

These cameras capture images at multiple wavelengths, including UV, visible, and IR light. They can reveal hidden details, underdrawings, and retouching in the mural that may not be visible to the naked eye. This information can provide insights into the mural's creation process and any alterations made over time.

Environmental monitoring equipment:

To understand the environmental conditions the mural has endured, researchers would need to use various sensors to measure temperature, humidity, light levels, and air quality at the site. This data can help assess the factors that may have influenced the mural's preservation and guide future conservation efforts.

Ground-penetrating radar (GPR) and other geophysical surveying tools: These instruments can help investigate the geological context of the mural site, including the characteristics of the rock face and any potential structural issues that may impact the mural's long-term preservation.

In addition to these specialized tools, researchers would also require standard equipment such as high-resolution digital cameras, 3D scanners, and GPS devices to document the mural and its surroundings accurately.

It is essential to note that the use of any equipment on the mural site must be done with the utmost care and under the guidance of experienced conservators to minimize any potential damage to the artwork. The data collected should be processed and analyzed by a multidisciplinary team of experts, including archaeologists, art historians, conservators, and physicists, to ensure a comprehensive understanding of the mural's significance and guide its preservation for future generations.

———-

To convey the data collected from the ancient mural site in Bamako, Mali to a database located in a colocation facility and powered by a geothermal baseload power plant, a robust data transmission and storage infrastructure would be necessary. This infrastructure should ensure the secure, efficient, and reliable transfer of data from the mural site to the colocation facility for long-term storage and analysis.

High-speed internet connectivity:

Fiber-optic cable:

A reliable, high-bandwidth fiber-optic internet connection should be established between the mural site and the colocation facility. This will ensure fast and stable data transmission, capable of handling large volumes of data generated by the various monitoring and imaging equipment.

Satellite communication:

As a backup to the fiber-optic connection, a satellite communication system can be employed to maintain data transmission in case of any terrestrial network disruptions.


On-site data storage and processing:

Rugged data storage devices: At the mural site, rugged, high-capacity data storage devices such as solid-state drives (SSDs) or external hard drives should be used to temporarily store data collected by the monitoring equipment. These devices must be able to withstand the environmental conditions at the site.

Field computers:

Rugged, portable computers will be needed to process and compress the data before transmission to the colocation facility. These computers should have sufficient processing power and memory to handle large datasets and run specialized software for data compression and encryption.


Data security and encryption:

Encryption software: All data transmitted from the mural site to the colocation facility must be encrypted to ensure its security and integrity. Robust encryption software and protocols, such as AES-256 or RSA, should be employed to protect the data during transmission.
Virtual Private Network (VPN): A VPN should be set up to create a secure, encrypted tunnel for data transmission between the mural site and the colocation facility, providing an additional layer of security.


Colocation facility infrastructure:

Servers and storage: The colocation facility should be equipped with high-performance servers and storage systems capable of handling the large volumes of data received from the mural site. These systems should have redundant components and be scalable to accommodate future growth in data volume.

Database management system:

A robust database management system, such as PostgreSQL, Oracle, or MongoDB, should be employed to organize, store, and manage the data received from the mural site. This system should be optimized for efficient data retrieval, analysis, and backup.

Backup and disaster recovery:

The colocation facility must have a comprehensive backup and disaster recovery plan to ensure the safety and integrity of the data. This should include regular data backups, off-site storage, and failover systems to minimize the risk of data loss.


Geothermal baseload power plant:

Uninterruptible power supply (UPS): The colocation facility should be equipped with a robust UPS system to ensure a stable, uninterrupted power supply to the servers and storage systems in case of any fluctuations or outages in the geothermal power supply.
Backup generators: As an additional precaution, backup generators should be installed at the colocation facility to maintain power supply in case of any issues with the geothermal power plant or the UPS system.



By establishing this robust data transmission and storage infrastructure, researchers can ensure the secure and efficient transfer of data from the ancient mural site in Bamako to the colocation facility, where it can be safely stored, managed, and analyzed for ongoing research and preservation efforts. The use of geothermal baseload power further enhances the sustainability and reliability of the data storage system.

———

To support the 50 MW nameplate geothermal facility and the data infrastructure required for the physics and artificial intelligence team of 500 people working on the ancient mural site in Bamako, Mali, a significant number of staff would be needed across various roles. This includes personnel for the geothermal power plant, IT infrastructure, and facility maintenance.

Geothermal power plant staff:

Plant managers: 2-3 experienced managers to oversee the overall operation of the geothermal power plant.

Control room operators: 8-10 skilled operators working in shifts to monitor and control the power plant's operations 24/7.

Maintenance technicians: 10-15 technicians, including mechanical, electrical, and instrumentation specialists, to perform routine maintenance and repairs on the power plant equipment.

Geologists and reservoir engineers: 2-3 experts to monitor and manage the geothermal reservoir, ensuring sustainable and efficient heat extraction.

Health, safety, and environment (HSE) officers: 2-3 HSE professionals to ensure compliance with safety regulations and environmental standards.


IT and data infrastructure staff:

Data center managers: 2-3 experienced managers to oversee the colocation facility's operations and ensure the smooth functioning of the data infrastructure.

Network engineers: 4-6 engineers to design, implement, and maintain the network infrastructure, including fiber-optic and satellite communications.

System administrators: 6-8 administrators to manage and maintain the servers, storage systems, and database management systems.

Cybersecurity specialists: 3-4 experts to implement and monitor data security measures, including encryption, access control, and intrusion detection.

IT support technicians: 8-10 technicians to provide technical support to the physics and artificial intelligence team, troubleshooting any issues with their computing resources.


Facility maintenance and support staff:

Electrical and mechanical technicians: 6-8 technicians to maintain the colocation facility's electrical and mechanical systems, including the UPS and backup generators.

HVAC technicians: 4-6 technicians to maintain the cooling systems required for the servers and computing equipment.

Janitorial and housekeeping staff: 8-10 staff members to keep the colocation facility clean and well-maintained.

Security personnel: 6-8 security guards working in shifts to ensure the physical security of the colocation facility and its assets.


Administrative and logistics staff

Project managers: 2-3 managers to coordinate the various teams and ensure the smooth operation of the entire project.

Procurement and logistics specialists: 3-4 staff members to manage the acquisition and delivery of necessary equipment, supplies, and services.

Human resources and finance personnel: 3-4 staff members to handle the recruitment, payroll, and other administrative tasks for the project staff.



In total, an estimated 100-150 staff members would be required to support the 50 MW nameplate geothermal facility and the data infrastructure for the physics and artificial intelligence team of 500 people. This ensures that the power supply remains stable, the data infrastructure is well-maintained and secure, and the research team has the necessary support to carry out their work on the ancient mural site in Bamako effectively.

It is important to note that these numbers are approximate and may vary depending on the specific requirements of the project, the complexity of the infrastructure, and the level of automation employed in various processes.