Description:SHORT DESCRIPTION OF DRAWINGS
Figure 1: Front View
Figure 2: Side view
Figure 3: Front skeleton view
Figure 4: Inside skeleton view

DETAILED DESCRIPTION OF THE INVENTION
The entire unit (101) has a dimension of 457.2 x 304.8 x 457.2 (LxWxH) from figure 1. (102) has as Seebeck effect device to control the inflow of the air which contain the humidity of the surrounding environment. The (103 and 104) has the seeebeck effect for the outflow during the condensation period.
From figure 2 the entire module is seen from the side view with a dimension as specified before and has an enclosed unit for more efficient air circulation (105). From figure 3 and figure 4 the inflow of the air and outflow is controlled by the controller with three fans (106, 107 and 108). The entire unit has an inner cylindrical wall (109) for easy air circulation. , C , C , Claims:Claim 1:
a. Utilizing the Seebeck effect to convert temperature gradients into electrical power;
b. Employing said electrical power to drive an atmospheric water generation (AWG) system;
c. Controlling and optimizing the AWG system's parameters using artificial intelligence (AI) algorithms, including real-time weather data and climatic predictions;
d. Condensing atmospheric moisture from the surrounding air to produce potable water.
Claim 2:
The method of claim 1, wherein the Seebeck effect is harnessed through the use of thermoelectric materials integrated into the AWG system.
Claim 3:
The method of claim 1, wherein the AI algorithms analyze local weather conditions, humidity levels, and temperature fluctuations to adapt the operation of the AWG system for enhanced efficiency.
Claim 4:
The method of claim 1, further comprising the step of purifying the condensed water to meet potable water standards before consumption.