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Kicad download for windows 2019- Kicad install

KiCad is a free licensed package (GPL) for the schematic capture of circuits and PCB layout. Before starting, you need to have a copy of Kicad download for windows 2019 to install. In this article show you how to download and install Kicad download for windows 2019 from here. It is assumed that KiCad is installed in C: \ Kicad. You can download a copy from the below download link.

Kicad download for windows 2019

Instructions for installation and work are available below. Follow the step by step guide A to Z direction.

1. Run “KiCad.exe”.

2. You will now be in the Main window.

3. Create a new project: “Projects” -> “New Project Descr”.

4. Click on the “Create New Folder” button, and name the folder as “Tute1”

5. Open the directory by clicking on it.

6. Enter the name of the project in “File Name”, for this tutorial we will call “tute1”. Click on “Save”. Note that the name of the project changed to “tute1”.

8. Double click on “tute1.sch”

9. An informative window will appear indicating that it is a new project. Make click on “OK”

10. You are now in the “EESchema” window. This window is used to introduce schemes.

11. First you must save the schematic project: “Files” -> “Save Schematic Project “.

12. Click on the “page settings” button in the top bar. Select “A4” as the size of the page (page size) and “Tute 1” as the title (Title)

13. Click on the “Add components” button located in the bar tools on the right right side.

15. Click on the center of the screen where you want to place the first component.

16. The “Component selection” dialog window will appear.

17. Click on “List All”. The “Select Lib” window will appear.

18. Double click on “device”.

19. The “Select Part” window will appear.

20. Move the scroll bar down and double click on “R”.

21. Press the ‘r’ key. Note how the component rotates.

22. Place the component in the center of the sheet by clicking the button left on the place where you want it.

23. Double click on the magnifying lens to zoom in on the component.

24. Right click on the center of the component.

25. Select: “Edit Component” -> “Edit”.

26. The “Component properties” window will appear.

27. Select the “Value” tab.

28. Replace the current value “Value” “R” with “1K”.

29. Click on “OK”.

30. Now the value of the resistance must be “1k”.

31. To place another resistance click on the place where you want it.

32. The “Component selection” window will appear.

33. The resistance you previously chose is in your history as “R”.

34. Click on “R”.

35. Place the resistance on the page.

36. Repeat and place a third resistance on the page.

37. Right click on the second resistance.

38. Click on “Delete Component”. This should delete the component.

39. Click with the right button on the third resistance. Select “Move Component “.

40. Reposition the component, click with the left button to release it.

41. Repeat steps 24-27 on the third resistance and replace “R” with “100”

42. Repeat steps 14 to 20, however, this time select

“Microcontrollers” instead of “device” and place “PIC12C508A” instead of “R”

43. Press the ‘y’ and ‘x’ keys. Observe how the component moves on its X and Y axes. Press ‘y’ and ‘x’ again to return to the original position.

44. Place the component on the page.

45. Repeat steps 14 to 20, this time select “device” and “LED”.

46. Organize the components on the page as follows:

47. Now we will add a component to the library.

48. Click on the “go to library editor” button in the toolbar higher.

49. The “Libedit” window will open.

50. Click on the “Select working library” button.

51. In the “select lib” window, click on “conn”.

52. Click on the “New part” button.

53. Name the new part as “MYCONN3”.

54. Enter the prefix as “J” and the number of parts as “1”.

55. If the warning “has a convert drawing” appears, click on “yes”.

56. In the center of the screen the name of the component should appear.

57. Double click on the magnifying glass to zoom in.

58. Click on the “Add Pins” button in the toolbar on the right.

Click with the left button on the screen where you want the pin.

59. In the “Pin Properties” box, enter the name of the pin as “VCC” and the pin number as “1”.

60. Select “Electrical Type” as “Power Out” then click on “OK”. Then to locate the pin, click where you want it to appear.

61. Repeat steps 59 to 61, this time “Pin Name” will be “INPUT” and “Pin Number “will be” 2 “. “Electrical Type” will be “Input”.

62. Repeat steps 59 to 61, now “Pin Name” will be “GND” and “Pin Number” It will be “3”. “Electrical Type” will be “Power Out”.

63. Place the pins and labels as shown in the figure in step 65.

65. Click on the “Add rectangle” button. By clicking with the left button and keeping the button pressed, a rectangle will be placed around the pin names.

66. Click on “Save current part into current loaded library (in memory)” in the top toolbar.

67. Click on “Save current loaded library on disk (file update)” in the bar of superior tools.

68. Click on “yes” in the confirmation message.

69. Now you can close the “Libedit” window.

70. Return to the “EeSchema” window.

71. Repeat steps 14 through 20, however, this time select “conn” and “MYCONN3”.

72. The new created part will appear. Select a place near the second resistance to place this component. Press the ‘y’ key to move it on the y axis.

73. The identifier of the “J?” Component will appear below the label “MYCONN3”. Right click on “J?” And then on “move” field “. Reposition “J?” Under the pins.

74. Click on the “Add powers” button in the toolbar of the right.

75. Click on the resistance pin of 1k.

76. In “Component Selection” clicks on list all.

77. In the “Select Part” window, scroll down and select “VCC”.

78. Click on the resistance pin of 1k to place the part.

79. Click on the VDD pin near the microcontroller.

80. In “Component Selection history” selects “VCC” and click again near the VDD pin.

81. Repeat again and place the VCC pin on the VCC pin of “MYCONN3”.

82. Repeat steps 74 through 76 but this time selects GND.

83. Place the GND pin under the GND pin of “MYCONN3”.

84. Place the small GND symbol on the right and below the VSS pin on the microcontroller.

85. Click on “Add wires” in the right toolbar ** Caution, Do not choose “Add bus” which appears just below but has more lines thick **

86. Click on the small circle at the end of pin 7 of the microcontroller and then on the small circle of pin 2 of the LED.

87. Repeat the process to wire the other components as shown below.

88. When placing the VCC and GND symbol wires, the wire should touch the lower part of the VCC symbol and in the middle of the top of the GND symbol.

89. Label the network by clicking on the “Add wire or bus label” button in the toolbar on the right.

90. Click on the middle of the cable between the microcontroller and the LED.

91. Enter the name “uCtoLED”.

92. Click near the circle of pin 7 (on the right) to place the name of the net.

93. Name the cable between the resistor and the LED as “LEDtoR”.

94. Name the cable between “MYCONN3” and the resistance as “INPUTtoR”.

95. Name the line to the right of the 100 ohm resistor as “INPUT”.

96. Name the line from pin 6 as “INPUT”. This creates an invisible connection between the two pins labeled “INPUT”. This is a useful technique in the case of complex designs that make the process of drawing the lines turn the drawing into something tangled.

97. You do not need to label the VCC and GND lines, the labels are implicit for the electrical objects to which they are connected.

98. The program automatically checks for errors, so any cable that is not connected will generate a warning. To avoid these warnings can tell the program that the unconnected cables are deliberate

99. Click on the “Add no connect” flag in the toolbar right.

100. Click on the small circle at the end of lines 2, 3, 4, and 5.

101. To add comments to the schema, use “Add graphics text (comment)” located in the toolbar on the right.

102. Now it is necessary to give unique identifiers to the components. For do this by clicking on the “Schematic Annotation” button.

103. In “EESchema Annotation” selects “Current Sheet” and “all components”.

104. Click on “Annotate”.

105. Click on “yes” in the confirmation message.

106. Notice how all the ‘?’ of the components have been replacements by numbers. Each identifier is unique. In our example “R1”, “R2”, “U1”, “D1” and “J1”.

107. Click on the “Schematic Electric Rules Check” button. Press the button “ERC Test”.

108. This will generate a report that will inform you about any errors or warning, like that of cables that are disconnected.

109. Click on “Netlist generation” at the top of the bar tools.

110. Click on “Netlist” then “save” to place the name by default.

111. Click on “Run Cvpvb” in the upper toolbar.

112. Cvpcb allows you to link fingerprints to the components.

113. On the light blue screen, select “D1” and drag it to the green screen, up to “LEDV” and double click on it.

114. For “J1” select the “3PIN_6mm” fingerprint.

115. For “R1” and “R2” select the trace “R1” on the light green screen.

116. Select 8dip300 for “U1”.

117. Click on “files” -> “Save netlist”. By default it is called “tute1.net”, which is fine, so click to save.

118. Save the project by clicking on “files” -> “Save Schematic Project”.

119. Switch to the main KiCad window.

120. Select “Browse” -> “Browse Files”.

121. If an error message appears, select your text search engine. Many computers have one in “c: \ windows \ notepad.exe”.

122. Select the file “tute1.net”; with this you will open the netlist file. East describes which components and which pins are connected to other pins.

123. Now go back to the “EeSchema” window.

124. To create a list of materials, click on the button “Bill of materials “in the toolbar at the top.

125. Click on “Create List” and then “Save”.

126. To see the file, repeat step 120 and select “tute1.lst”.

127. Now click on the “Run Pcbnew” button in the toolbar higher.

128. The “Pcbnew” window will open.

129. Click on “OK” in the error message, for the non-existent file.

130. Click on “files” -> “Save board”.

131. Click on the “page settings” button in the toolbar higher.

132. Select “A4” in “paper size” and enter “Tute 1” as the title.

133. Click on “Dimensions” -> “Tracks and Vias”.

134. Select the configurations to match the capabilities from the manufacturer of your PCB. (Consult the manufacturer of your PCB to obtain this information.) For this example increase “clearance” to 0.0150 “.

135. Click on the “Read Netlist” button in the toolbar higher.

136. Click on the “Select” button, select “tute1.net”, click on “Open” and the “Read” button. Then click on the “Close” button.

137. The components will be located in the upper left corner in the top of the page, slide up to see them.

138. Click with the right mouse button and select “move component” and place it in the middle of the page.

139. Repeat the previous steps until all the components are found in the center of the page.

140. Make sure that the “General rats nest not show” button is activated.

141. This will show the rats net, which is a set of lines that show which pins are connected.

142. Move the components until you minimize the crossings between lines in the rats nest.

143. If the rats nest disappears or becomes very complex click with the button right mouse and then select “redraw”.

144. Now connect everything, except the cables to ground, in “component side” (layer higher).

145. Click on the “Add Tracks a vias” button in the toolbar right.

146. Select “Component” from the drop-down menu located in the toolbar superior tools.

147. Click on the center of pin 1 of “J1” and take a line to “R2”.

148. Repeat is these steps until all the cables, except pin 3 of J1, are connected

149. In the drop-down menu of the top toolbar select “Copper” (lower layer).

150. Click on the “Add tracks and vias” button (step 145).

151. Draw a line between pin 3 of J1 and pin 8 of U1.

152. Click on the “Net highlight” button in the toolbar to the right.

153. Click on pin 3 of J1, It should turn yellow.

154. Click on the “Add Zones” button in the toolbar to the right.

155. Draw the outline of the board.

156. Right-click on the area you have just placed.

157. Click on “Fill Zones”.

158. Select “Grid” “0.010”, “Pad options:” “Thermal”, “Zone edges orient:” “H, V” and then click on “Fill”.

159. Your board should look like this.

160. Now select “Edges Pcb” in the drop-down menu in the bar superior tools.

161. Select the “Add graphic line or polygon” button in the bar tools on the right.

162. Draw a border around the board but remember to leave a small space between the green border and the edge of the PCB.

163. Execute the design correction rules by clicking on “Pcb Design Rules Check “.

164. Click on “DRC Test”. There should be no errors.

165. Click on “List Unconn”. There should be no components without connecting.

166. Save your project by clicking on “files” -> “Save board”.

167. To see your board in 3D, click on “3D Display” -> “3D Display”.

168. You can drag the mouse to rotate the PCB.

169. Your board is complete; to send it to a manufacturer you will need to generate a GERBER file.

170. Click on “files” -> “plot”.

171. Select GERBER as “plot format” and click on plot.

172 To view GERBER files, go to the main KiCad window.

173. Click on the “GerbView” button.

174. Click on “files” -> “Load GERBER file”.

175. Select the file name “tute1_Copper.pho” and then “open”.

176. In the drop-down menu select “Layer2”.

177. Repeat steps 174 and 175, but this time load “tute1_component.pho”.

178. Repeat step 176 but select “Layer 3” then step 174 and 175 but now load “tute1_SlkSCmp.pho”.

179. In this way you can examine the layers that will be sent to production.

There are an extensive number of fingerprint libraries next to KiCad, However; sometimes you will not find the footprint you need. Here are some steps to create a footprint that you can use in KiCad.

180. To create a new footprint for the PCB, change back to “PCBnew”.

181. Click on “Open Module Editor” in the upper toolbar.

182. The “Module Editor” will open.

183. Click on “select working library” in the upper toolbar.

184. For this exercise, select the “connect” library.

185. Click on the “New Module” button in the toolbar higher.

186. Enter “MYCONN3” as “module reference”.

187. The label “MYCONN3” will appear in the middle of the screen.

188. Below the label will be “VAL **”.

189. Right click on “MYCONN3” and move it on “VAL **”.

190. Click on “VAL **”, select “Edit Text Mod” and rename it as “SMD”.

191. Check the option “no display”.

192. Select “Add Pads” in the right toolbar.

193. Click on the screen to locate the pad.

194. Click with the right mouse button on the new pad and then in “edit”.

195. Set “Pad Num” equal to “1”, “Pad Size X” equal to “0.4”, “Pad Size Y” equal to “0.8”, “Pad Shape” equal to “Rect” and “Pad Type” equal to “SMD”. Click in “Ok”.

196. Again click on “Add Pads” and locate 2 more pads.

197. Move the labels “MYCONN3” and “SMD” so that they are visible over.

198. Click on the “Add graphic line or polygon” button in the bar right tools.

199. Draw the outline of the connector around the component.

200. Click on “Save Module in working directory” in the bar superior tools.

201. Now you can go back to PCB new and click on the “Add modules” button in the right toolbar.

202. Click on the screen and the name of the module will appear.

203. Select the module “MYCONN3” and place it in your design.

This Kicad download for windows 2019 has been a short article on most of KiCad’s features. For more detailed instructions, there is a help file that can be opened at any time, from any KiCad module. For this click on “help”.


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