Posts

Showing posts with the label Mauna Loa

Space Facts: Part 4 - Celestial Dust, Kepler 289

-
1. What is Celestial Dust: Cluster of galaxy: Abell 1698 , A1698-ZD1 galaxy in galaxy cluster of Abel 1698 is full of space dust. Dust is made up of Silicon, Iron, Oxygen, Magnesium, Carbon, etc. Elements and dust are formed in stars by nuclear processes from gases like Helium and Hydrogen. When star dies dust and gases are emitted. So dust was formed only after bigbang happened. 2. Kepler 289 Star: PH3c (Kepler 289c) is a dwarf planet discovered in solar system of PH3 star. PH3c planet has irregular revolution time due to external gravitational force from other planets affecting the planet's revolution. Other planets of that solar-system are PH3b (Kepler 289b) and PH3d (Kelper 289d).  PH3b and PH3d planets are very massive in size as compared to PHc so they pull the planets towards themselves when PH3 passes near them, changing the revolution orbit of PH3c. Astronomers estimate that after millions of years PH3c will be removed outside solar system by gravity-pul...
Post a Comment
Read more

Popular posts from this blog

Verilog: 8 to 1 Multiplexer (8-1 MUX) Dataflow Modelling with Testbench Code

-
Image
  Verilog Code for 8 to 1 Multiplexer Dataflow Modelling module mux_8to1(     input a, input b, input c, input D0, input D1, input D2, input D3, input D4, input D5, input D6, input D7, output out, ); module m81( output out, input D0, D1, D2, D3, D4, D5, D6, D7, S0, S1, S2); assign S1bar=~S1; assign S0bar=~S0; assign S2bar=~S2; assign out = (D0 & S2bar & S1bar & S0bar) | (D1 & S2bar & S1bar & S0) | (D2 & S2bar & S1 & S0bar) + (D3 & S2bar & S1 & S0) + (D4 & S2 & S1bar & S0bar) + (D5 & S2 & S1bar & S0) + (D6 & S2 & S1 & S0bar) + (D7 & S2 & S1 & S0); endmodule //Testbench code for 8-1 MUX Dataflow Modelling initial begin // Initialize Inputs a= 0;b = 0;c = 0;D0 = 1;D1 = 0;D2 = 0;D3 = 0;D4 = 0;D5 = 0;D6 = 0;D7 = 0; // Wait 100 ns for global reset to finish #100; // Add stimulus here #100; a = 0;b = 0;c = 1;d0 = ...
Read more

VLSI: 1-4 DEMUX (Demultiplexer) Dataflow Modelling with Testbench

-
Image
Verilog Code for 1-4 DEMUX Dataflow Modelling module demux_1_to_4(     input d,     input s0,     input s1,     output y0,     output y1,     output y2,     output y3     ); assign s1n = ~ s1; assign s0n = ~ s0; assign y0 = d& s0n & s1n; assign y1 = d & s0 & s1n; assign y2 = d & s0n & s1; assign y3 = d & s0 & s1; endmodule //Testbench code for 1-4 DEMUX Dataflow Modelling initial begin                              // Initialize Inputs ...
Read more

VLSI: 4-1 MUX Dataflow Modelling with Testbench

-
Image
Verilog Code for 4-1 MUX Dataflow Modelling module m41(out, i0, i1, i2, i3, s0, s1); output out; input i0, i1, i2, i3, s0, s1; assign y0 = (i0 & (~s0) & (~s1)); assign y1 = (i1 & (~s0) & s1); assign y2 = (i2 & s0 & (~s1)); assign y3 = (i3 & s0 & s1); assign out = (y0 | y1 | y2 | y3); endmodule //Testbench code for 4-1 MUX Dataflow Modelling initial begin                              // Initialize Inputs                              a = 1;b = 0;c = 0;d = 0;s0 = 0;s1 = 0;        ...
Read more

VLSI: Half Subtractor and Full Subtractor Gate Level Modelling

-
Image
Half Subtractor: Verilog Module Code: module half_subtractor (      input  a,      input  b,      output  diff       output  borr ); wire x; xor (diff,a,b); not (x,a); and (borr,x,b); endmodule Full Subtractor: Verilog Module Code: module full_subtractor (      input  a,      input  b,      input  c,      output  diff       output  borr ); wire x,n2,z,n1; xor s1(x,a,b); not s3(n2,x); not s4(n1,c); and s5(y,n1,b); xor s2(diff,a,x); and s6(z,n2,a); or (borr,y,z); endmodule
Read more

Full Subtractor Verilog Code in Structural/Gate Level Modelling with Testbench

-
Image
Verilog Code for Full Subtractor Structural/Gate Level Modelling module  full_sub(borrow,diff,a,b,c); output  borrow,diff; input  a,b,c; wire w1,w4,w5,w6; xor (diff,a,b,c); not n1(w1,a); and a1(w4,w1,b); and a2(w5,w1,c); and a3(w6,b,c); or o1(borrow,w4,w5,w6); endmodule //Testbench code for Full Subtractor Structural/Gate Level Modelling initial  begin // Initialize Inputs a = 0; b = 0; c = 0; // Wait 100 ns for global reset to finish #100; // Add stimulus here #100; a = 0;b = 0;c = 1; #100; a = 0;b = 1;c = 0; #100; a = 0;b = 1;c = 1; #100; a = 1;b = 0;c = 0; #100; a = 1;b = 0;c = 1; #100; a = 1;b = 1;c = 0; #100; a = 1;b = 1;c = 1; end Output: RTL Schematic: Full Subtractor Verilog Other Verilog Programs: Go to Index of  Verilog Programming
Read more