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Components for Antavlan, a Swedish board game that my wife brought back from her trip in summer of 2006.
via Electronic Components www.pinterest.com/pin/421649583832944240/
Click for More Electronic Components at pinterest.com/componentshub/electronic-components/
Attempt at capturing the reflected light off the components.
No photoshop, lightshop or gimp effects....Au Natural
Yep, basically components of my day - here's some nail varnished fingers, a rice cake and the internet. How I like Saturdays.
98/365
Component parts of my modular house boat, including a ladder, a keyboard and mouse, a desk chair, a sofa and flooring fo the first level. Mountboard, PVA glue, PVC pipe shavings, cork and burlap were all used.
From 31 July to 2 August 2018, several Heads of UN missions Police chiefs meet in Addis Ababa at the 3rd Heads of Police Components Retreat. Their counterparts from African Union missions and hybrid AU-UN missions as well from the Federal Police Commission of Ethiopia are also attending the retreat. The main objective is to utilize this retreat as a platform for sharing and exchanging ideas/best practices within a regional context. Two other preceding similar retreats were held in Entebbe and Kigali.
hyper-realistic image of a hypothetical AI motherboard integrating wetware components would represent a fusion of biological computing elements with traditional electronic circuits. Here's how it could work:
Biocomputing Interface: The wetware component would be a biologically active substrate, like synthetic neural tissue, capable of processing information. It would be connected to the electronic circuits through a biocompatible interface that translates electronic signals into biological responses and vice versa.
Synthetic Neurons: These neurons could form networks that mimic the function of human brain cells, capable of learning and adapting.
Data Processing: The synthetic neural networks could handle complex pattern recognition tasks, data analysis, and learning algorithms more efficiently than traditional silicon-based CPUs.
Energy Management: Wetware may require different power management solutions to maintain the viability of the biological components.
Thermal Regulation: Given the sensitivity of biological components to temperature, the system would need advanced cooling mechanisms.
Signal Transmission: Specialized transceivers would handle communication between the wetware and hardware, ensuring seamless data transfer.
Maintenance Systems: Nutrient supply systems and waste removal mechanisms would be necessary to keep the biological components functional.
LED Lights: These would provide visual feedback on the operational status of both the electronic and wetware components.
LCD Display: This could display the system status or provide a user interface for monitoring or interacting with the AI system.
In a hypothetical diagram:
The CPU would be in the center, with electronic pathways branching out.
Synthetic neural tissue would be placed strategically, possibly above the CPU, with connections leading to various parts of the motherboard.
Power lines would supply energy to both the electronic and wetware components.
Cooling systems would be depicted around the wetware, showing their role in maintaining optimal temperatures.
Nutrient and waste channels would be illustrated, connecting the wetware to reservoirs and disposal systems.
Transceivers for signal transmission would be situated at the interfaces between the wetware and electronic circuits.
LED lights would line the primary pathways, with the LCD display situated on the edge of the motherboard for easy access.
Creating an actual diagram requires detailed knowledge of biocomputing and electronic engineering to ensure accurate representation of such a complex system.