This document discusses problems applying Ohm's Law and Watt's Law. It contains information on color codes for electronic components like resistors, the parts and uses of breadboards or protoboards, and examples of applying Ohm's Law and Watt's Law to calculate values like resistance, current, voltage and power in simple circuits. Blog links are provided for each group member. Evidence photos from building circuits on a breadboard are included at the end.
This document discusses problems applying Ohm's Law and Watt's Law. It begins with explanations of color coding used to identify electronic component values and protoboards used for building and testing circuits. Several example problems are provided that demonstrate calculating current, voltage, resistance, and power using formulas from Ohm's and Watt's Laws. The conclusions note that color coding identifies component values, protoboards aid in circuit testing, and formulas can be used to find current, voltage, resistance and power when applying Ohm's and Watt's Laws to circuit problems.
This document discusses color coding of electronic components, protoboards, and problems applying Ohm's Law and Watt's Law. It begins with explanations of the color coding system used for resistors and other components, showing how colored bands indicate values and tolerances. It then describes the layout and uses of protoboards for assembling and testing circuits. The document concludes by presenting several example problems that demonstrate calculating current, voltage, resistance, and power using formulas from Ohm's and Watt's Laws.
This document summarizes a student project on applying Ohm's Law and Watt's Law. It includes solutions to 13 practice problems applying the laws to calculate values like resistance, current, voltage and power in different circuits. It also discusses color codes used for electronic components and the use of a breadboard for building temporary circuits. The conclusions reiterate that the project helped strengthen understanding of Ohm's and Watt's Laws. Evidence photos from experiments are included, along with links to the individual student blogs.
Problemas de aplicación ley de ohm y ley de watt (1)DiegoPiedrahita9
This document presents solutions to exercises applying Ohm's Law and Watt's Law. It begins with an introduction to color codes used in electronics components and protoboards. It then shows the work and solutions to 13 exercises involving calculating resistance, current, voltage or power given values for other variables. The conclusions reiterate the importance of reinforcing understanding of Ohm's and Watt's Laws. Evidence photos and links to related student blogs are also included.
This document contains information about several transistor amplifier circuits. It discusses the feedback pair circuit, which is similar to a Darlington pair but connects a PNP transistor to control an NPN transistor. It also describes the differential amplifier circuit, which amplifies the difference between two input voltages and suppresses any common voltage. Finally, it provides examples of circuit analysis questions involving determining currents and voltages in circuits using transistors.
This document discusses problems applying Ohm's Law and Watt's Law. It contains information on color codes for electronic components like resistors, the parts and uses of breadboards or protoboards, and examples of applying Ohm's Law and Watt's Law to calculate values like resistance, current, voltage and power in simple circuits. Blog links are provided for each group member. Evidence photos from building circuits on a breadboard are included at the end.
This document discusses problems applying Ohm's Law and Watt's Law. It begins with explanations of color coding used to identify electronic component values and protoboards used for building and testing circuits. Several example problems are provided that demonstrate calculating current, voltage, resistance, and power using formulas from Ohm's and Watt's Laws. The conclusions note that color coding identifies component values, protoboards aid in circuit testing, and formulas can be used to find current, voltage, resistance and power when applying Ohm's and Watt's Laws to circuit problems.
This document discusses color coding of electronic components, protoboards, and problems applying Ohm's Law and Watt's Law. It begins with explanations of the color coding system used for resistors and other components, showing how colored bands indicate values and tolerances. It then describes the layout and uses of protoboards for assembling and testing circuits. The document concludes by presenting several example problems that demonstrate calculating current, voltage, resistance, and power using formulas from Ohm's and Watt's Laws.
This document summarizes a student project on applying Ohm's Law and Watt's Law. It includes solutions to 13 practice problems applying the laws to calculate values like resistance, current, voltage and power in different circuits. It also discusses color codes used for electronic components and the use of a breadboard for building temporary circuits. The conclusions reiterate that the project helped strengthen understanding of Ohm's and Watt's Laws. Evidence photos from experiments are included, along with links to the individual student blogs.
Problemas de aplicación ley de ohm y ley de watt (1)DiegoPiedrahita9
This document presents solutions to exercises applying Ohm's Law and Watt's Law. It begins with an introduction to color codes used in electronics components and protoboards. It then shows the work and solutions to 13 exercises involving calculating resistance, current, voltage or power given values for other variables. The conclusions reiterate the importance of reinforcing understanding of Ohm's and Watt's Laws. Evidence photos and links to related student blogs are also included.
This document contains information about several transistor amplifier circuits. It discusses the feedback pair circuit, which is similar to a Darlington pair but connects a PNP transistor to control an NPN transistor. It also describes the differential amplifier circuit, which amplifies the difference between two input voltages and suppresses any common voltage. Finally, it provides examples of circuit analysis questions involving determining currents and voltages in circuits using transistors.
Problemas de aplicación ley de ohm y ley de wattDanielaAvendao14
This document discusses problems applying Ohm's Law and Watt's Law. It contains information on color codes for electronic components like resistors, the parts and uses of breadboards, and examples solving for voltage, current, resistance, and power in circuits. The conclusions are that color codes indicate resistor values and breadboards make building circuits easier without soldering. Links to related blogs and evidence of student work are also included.
This document discusses color codes, protoboards, and solving circuit problems. It begins with explaining color codes used to define a website's color palette using RGB, hexadecimal, and HSL systems. It then describes the purpose and structure of a protoboard, including its central channel, buses, and tracks. The document provides examples of circuit calculations using Ohm's Law and Watt's Law to find values like resistance, voltage, current and power. Images are included to illustrate the concepts.
Problemas de aplicación ley de ohm y ley de wattNathaliaSalas5
This document discusses problems applying Ohm's Law and Watt's Law. It begins with explanations of color coding for electronic components and how protoboards are used. It then provides examples of problems applying the laws, such as calculating resistance given voltage and current, or power given voltage and current. The conclusions note that color coding identifies component values, protoboards allow experimental circuits, and formulas can be used to calculate values like resistance, current, voltage, and power.
This document discusses problems applying Ohm's Law and Watt's Law. It begins with explanations of color coding for electronic components and how protoboards are used. It then provides examples of problems applying the laws, such as calculating resistance given voltage and current, or power given voltage and current. The conclusions note that color coding identifies component values, protoboards allow experimental circuits, and formulas can be used to calculate values like resistance, current, voltage, and power.
This document discusses problems applying Ohm's Law and Watt's Law. It begins with explanations of color coding used to identify electronic component values and protoboards used for building and testing circuits. Several example problems are provided that demonstrate calculating current, voltage, resistance, and power using formulas from Ohm's Law and Watt's Law. The conclusions note that color coding identifies component values, protoboards aid in circuit testing, and formulas can be used to find current, voltage, resistance and power when applying Ohm's and Watt's Laws to circuit problems.
This document discusses problems applying Ohm's Law and Watt's Law. It begins with explanations of color coding used to identify electronic component values and protoboards used for building and testing circuits. Several example problems are provided that demonstrate calculating current, voltage, resistance, and power using formulas from Ohm's Law and Watt's Law. The conclusions note that color coding identifies component values, protoboards aid in circuit testing, and formulas can be used to find current, voltage, resistance and power when applying Ohm's and Watt's Laws to circuit problems.
Problemas de aplicación ley de ohm y ley de wattKatheryncaicedo1
This document discusses color coding, breadboards, and exercises applying Ohm's law and Watt's law. It begins by explaining color coding for electronic components like resistors and how to use the color bands to determine a resistor's value. It then defines and describes the purpose and structure of a breadboard for prototyping circuits. The document concludes with examples solving for current, voltage, resistance, and power in various circuit scenarios.
Problemas de aplicación ley de ohm y ley de wattValeriaDavila6
This document discusses problems applying Ohm's Law and Watt's Law. It begins by explaining color codes used on resistors to indicate resistance, tolerance, and other parameters. It then defines a breadboard (protoboard), explaining that it is a temporary PCB used for testing circuit prototypes by inserting component leads into holes. The document concludes by presenting 13 sample problems applying Ohm's Law and Watt's Law to calculate values like resistance, voltage, and power given other known values in various circuit scenarios.
This document discusses problems applying Ohm's law and Watt's law. It begins by explaining color codes used for resistors and introduces the protoboard, a tool used for prototyping circuits. Examples are given of calculating resistance, voltage, and power using Ohm's and Watt's laws. The conclusion reiterates that a protoboard allows modifying circuits easily and color codes determine resistor values. Problems demonstrate computations for resistance, voltage, current, and power.
Tecnología#2 (Problemas de Aplicaicon Ley de OHM y Ley de Watt)AndresPerera2
Trabajo realizado por los estudiantes de grado 10-5: Angie Sophie Medina Ibarra, Juan Sebastián Sánchez Valencia, María José Pareja Ramírez, Jacobo Paredes Rico Valentina Mosquera Arenas.
This document discusses problems with applying Ohm's law and Watt's law. It begins with an introduction to color coding used for electrical components like resistors. It then explains what a protoboard is and its main parts. The document presents example problems applying Ohm's and Watt's laws. It concludes that the investigations help understand how to apply the laws and solve related problems logically. References and links to related blogs are also included.
The document discusses the color code system used in electronics to indicate the values of components like resistors. It originated in the 1920s in the US and was standardized internationally. It explains how to read color codes on resistors and other components. The document also describes protoboards, which are plastic boards with holes for building and testing simple circuits with components like batteries, switches, resistors and LEDs. It concludes that color codes and protoboards are useful tools for learning electronics.
Problemas de aplicación ley de ohm y ley de wattNicolas1128
This document discusses the application problems of Ohm's law and Watt's law. It begins by explaining Ohm's law, which determines the relationship between voltage, current and resistance in an electrical circuit. It then explains Watt's law, which determines the rate at which electrical power is transferred through a circuit. The document also covers color coding systems for electronic components like resistors and provides examples of solving circuit problems using Ohm's and Watt's laws. It concludes that these laws are fundamental tools for understanding many natural and artificial phenomena related to electrical circuits.
This document discusses problems applying Ohm's law and Watt's law. It provides information on color codes for resistors and capacitors. It then provides examples of applying Ohm's law and Watt's law to solve circuit problems involving voltage, current, resistance and power. References and blogs related to electrical fundamentals are listed at the end.
Problemas de aplicación de ley de ohm y ley de wattjeanmarco
This document discusses problems applying Ohm's law and Watt's law. It begins with explanations of color codes, protoboards, Ohm's law, and Watt's law. It then provides examples of solving circuit problems using these laws, such as calculating resistance, voltage, or power given other values. It concludes that electrical power is directly proportional to voltage and current, and applications of Ohm's law establish the relationships between current, voltage, and resistance in a circuit.
This document discusses problems applying Ohm's law and Watt's law. It provides the color codes for resistors, capacitors, and protoboards. It then works through 14 example problems of applying Ohm's and Watt's laws to calculate values like resistance, voltage, and power for various circuit elements. The conclusions reiterate the learning gained about solving electrical circuit problems. References and relevant blogs are also listed.
This document discusses problems applying Ohm's law and Watt's law. It provides the color codes for resistors, capacitors, and protoboards. It then works through 14 practice problems applying Ohm's law and Watt's law to calculate values like resistance, voltage, and power given other known values. The conclusions reiterate the learning gained from working through the practice problems on electrical circuit concepts. References and relevant blogs are also listed.
This document discusses problems applying Ohm's law and Watt's law. It provides the color codes for resistors, capacitors, and protoboards. It then works through 14 practice problems applying Ohm's law and Watt's law to calculate values like resistance, voltage, and power given other known values. The conclusions reiterate the learning gained from working through the practice problems on electrical circuit concepts. References and relevant blogs are also listed.
This document discusses problems applying Ohm's law and Watt's law. It provides the color codes for resistors, capacitors, and protoboards. It then works through 14 practice problems applying Ohm's law and Watt's law to calculate values like resistance, voltage, and power given other known values. The conclusions reiterate the learning gained from working through the practice problems on electrical circuit concepts. References and relevant blogs are also listed.
This document discusses color codes for electrical components like resistors and capacitors. It also explains how to use a protoboard to build circuits and solve problems related to Ohm's Law and Watt's Law. The document is a report submitted by a group of students for their technology and information class containing content on color codes, a protoboard diagram, and solutions to 14 practice problems applying equations for resistance, voltage, current and power.
El documento presenta resúmenes de varias charlas sobre el cuidado del medio ambiente que tuvieron lugar en la ciudad de Cali. En las charlas, diferentes organizaciones ambientales como el grupo SSAE, la empresa Cali Limpia, el grupo de recicladoras, la CVC y el DAGMA discutieron problemas ambientales en Cali como la contaminación, la mala gestión de residuos sólidos y la importancia de generar conciencia ciudadana para mitigar estos problemas y lograr una ciudad más sostenible. Cada organización propuso estrategias como campañas de
This short document appears to be discussing protective periods and periodontists. It contains two words that seem related to dental health: "periodontists", who are specialists in treating gum disease and other diseases of the tissues and bones supporting the teeth, and "periodist", which may refer to periods of time that involve protection. The connection between these two words is unclear from the limited information provided.
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This document discusses problems applying Ohm's Law and Watt's Law. It contains information on color codes for electronic components like resistors, the parts and uses of breadboards, and examples solving for voltage, current, resistance, and power in circuits. The conclusions are that color codes indicate resistor values and breadboards make building circuits easier without soldering. Links to related blogs and evidence of student work are also included.
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This document discusses problems applying Ohm's Law and Watt's Law. It begins with explanations of color coding used to identify electronic component values and protoboards used for building and testing circuits. Several example problems are provided that demonstrate calculating current, voltage, resistance, and power using formulas from Ohm's Law and Watt's Law. The conclusions note that color coding identifies component values, protoboards aid in circuit testing, and formulas can be used to find current, voltage, resistance and power when applying Ohm's and Watt's Laws to circuit problems.
This document discusses problems applying Ohm's Law and Watt's Law. It begins with explanations of color coding used to identify electronic component values and protoboards used for building and testing circuits. Several example problems are provided that demonstrate calculating current, voltage, resistance, and power using formulas from Ohm's Law and Watt's Law. The conclusions note that color coding identifies component values, protoboards aid in circuit testing, and formulas can be used to find current, voltage, resistance and power when applying Ohm's and Watt's Laws to circuit problems.
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This document discusses color coding, breadboards, and exercises applying Ohm's law and Watt's law. It begins by explaining color coding for electronic components like resistors and how to use the color bands to determine a resistor's value. It then defines and describes the purpose and structure of a breadboard for prototyping circuits. The document concludes with examples solving for current, voltage, resistance, and power in various circuit scenarios.
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This document discusses problems applying Ohm's Law and Watt's Law. It begins by explaining color codes used on resistors to indicate resistance, tolerance, and other parameters. It then defines a breadboard (protoboard), explaining that it is a temporary PCB used for testing circuit prototypes by inserting component leads into holes. The document concludes by presenting 13 sample problems applying Ohm's Law and Watt's Law to calculate values like resistance, voltage, and power given other known values in various circuit scenarios.
This document discusses problems applying Ohm's law and Watt's law. It begins by explaining color codes used for resistors and introduces the protoboard, a tool used for prototyping circuits. Examples are given of calculating resistance, voltage, and power using Ohm's and Watt's laws. The conclusion reiterates that a protoboard allows modifying circuits easily and color codes determine resistor values. Problems demonstrate computations for resistance, voltage, current, and power.
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This document discusses problems with applying Ohm's law and Watt's law. It begins with an introduction to color coding used for electrical components like resistors. It then explains what a protoboard is and its main parts. The document presents example problems applying Ohm's and Watt's laws. It concludes that the investigations help understand how to apply the laws and solve related problems logically. References and links to related blogs are also included.
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This document discusses the application problems of Ohm's law and Watt's law. It begins by explaining Ohm's law, which determines the relationship between voltage, current and resistance in an electrical circuit. It then explains Watt's law, which determines the rate at which electrical power is transferred through a circuit. The document also covers color coding systems for electronic components like resistors and provides examples of solving circuit problems using Ohm's and Watt's laws. It concludes that these laws are fundamental tools for understanding many natural and artificial phenomena related to electrical circuits.
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Problemas de aplicación de ley de ohm y ley de wattjeanmarco
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- Hands-on examples and code snippets in Jupyter Notebooks to help you implement and test anomaly detection models.
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Problemas de aplicación ley de ohm y ley de watt
1. Problemas de Aplicación Ley de OHM y Ley de Watt
Jhoan Sebastian Arias, Juan José Gonzalez, Samuel David León y Laura Sofía Torres
Departamento de Tecnología e Informática, Institución Educativa Liceo Departamental
Grado 10-1
A12: Tecnología e Informática
Guillermo Mondragón
28 de junio del 2021
2. 2
Tabla de contenido
1. Código de colores………………………………………………...……………………3
2. Protoboard…………...…………………………………………………………………5
3. Problemas adicionales.…………………………………………...……………………7
4. Conclusiones..……...…………………………………………………………………10
5. Blogs del curso...…...…………………………………………………………………11
6. Evidencias de trabajo.……………....……………………………...…………………11
7. Referencias……….....…………………………………………...……………………16
3. 3
1. Código de colores
Los códigos de colores son formas de representar los colores que se pueden observar
en los formatos que un computador puede interpretar y mostrar. Generalmente es utilizado en
sitios web y aplicaciones de software, en los cuales incluye una gran variedad de formatos,
además de tener códigos HEX. RGB y HSL, que son valores y nombres de colores HTML,
etc.
1.1. Código de colores HTML
Para construir un color en HTML, se debe de utilizar la combinación de tres colores
primarios, que en este caso son rojo, verde y azul, los cuales pueden adquirir un valor entre 0
y 255, que representan su participación en la mezcla de colores, donde 255 es la máxima
participación y 0 es la mínima.
De este modo, cada código HTML comprende un símbolo de numeral (“#”), que se
acompaña de 6 letras o números, según la intensidad de los colores rojo, verde y azul,
expresados en un sistema de numeración hexadecimal.
1.2. Significado de los símbolos
Los dos primeros símbolos en el código HTML representan la pigmentación del color
rojo, (00 es menor intensidad y FF es mayor intensidad). El tercer y cuarto número estarían
representando la intensidad del color verde, y por último, el quinto y sexto número
representan la intensidad del color azul. Finalmente, con la combinación de estos tres colores
según su intensidad se puede crear cualquier tonalidad que se desee.
Ejemplos:
Con el código #00FFFF se consigue el color cyan o aqua. Ver figura 1.
4. 4
Fig. 1.
Con el código #FFFF00 se obtiene el color amarillo. Ver figura 1.1.
5. 5
Fig. 1.1.
2. Protoboard
¿Qué es?
El protoboard es un dispositivo muy utilizado para probar circuitos eléctricos. Tiene la
ventaja de que permite armar con facilidad un circuito, sin la necesidad de realizar soldaduras.
Cómo se usa.
El protoboard está dividido en tres áreas principales que son el canal central, los buses
y las pistas.
1) Canal central: está localizado en el centro de la placa de inserción o protoboard
y tiene como función colocar los circuitos integrados.
6. 6
2) Los buses tienen conexión y por ende conducen a todo lo largo (aunque algunos
fabricantes dividen ese largo en dos partes).
Las líneas rojas y azules te indican cómo conducen los buses. No existe conexión
física entre ellos, es decir, no hay conducción entre las líneas rojas y azules.
En los buses se acostumbra a conectar la fuente de poder que usan los circuitos o las
señales que quieres inyectar a ellos desde un equipo externo. Por su parte, las pistas (en
morado) te proveen puntos de contacto para los pines o terminales de los componentes que
colocas en el protoboard siguiendo el esquemático de tu circuito, y conducen como están
dibujadas. Son iguales en todo el protoboard. Las líneas moradas no tienen conexión física
entre ellas.
Fig. 2.
Estos funcionan como minibuses y se usan para interconectar los puntos comunes de
los circuitos que montas. Cuando no te alcanzan los huecos disponibles, puedes llevar un
cable desde la pista de interés a otra que esté libre y continuar allí sus conexiones.
7. 7
3) Las pistas: en la parte central , existe un canal más ancho. Esto se hace para que los
chips o integrados puedan calzar adecuadamente en las pistas, como las dimensiones de los
encapsulados están normalizados cualquier chip que coloques podrás ajustarlo.
Fig. 2.1.
A= Canal central
B= Buses
C= pistas
3. Problemas adicionales de Ley de OHM y potencia
1) Un circuito consiste de una batería de 6 V, un interruptor y una lámpara. Cuando el
interruptor está cerrado, en el circuito fluye una corriente de 2. A. ¿Cuál es la resistencia de la
lámpara?
Solución: 𝑅 =
𝑉
𝐼
𝑅 =
6𝑉
2𝐴
𝑅 = 3Ω
La resistencia de la lámpara es: 3Ω
3) En los extremos de un resistor de 200 se mide un voltaje de 20 V. ¿Cual es la
Ω
corriente que pasa por el resistor?
8. 8
Solución: 𝐼 =
𝑉
𝑅
𝐼 =
20𝑉
200Ω
A
𝐼 = 0. 1
La corriente que pasa por el resistor es: 0.1 A
5) El filamento de un tubo de televisión tiene una resistencia de 90 . ¿Qué voltaje se
Ω
requiere para producir las especificaciones de 0.3 A?
Solución: 𝑉 = 𝐼. 𝑅
A 90
𝑉 = 0, 3 . Ω
𝑉 = 27
El voltaje que se requiere para producir las especificaciones de 0.3 A es: 27 V
9) Una bobina de relevador telegráfico de 160 opera con un voltaje de 6.4 V
Ω
.Encuéntrese la corriente que consume el relevador.
Solución:𝐼 =
𝑉
𝑅
𝐼 =
160
6.4
I=0.04 A
El relevador consume 0.04 A.
11) Una batería de 12V está conectada a una lámpara que tiene resistencia de 10 .
Ω
¿Qué potencia suministra a la carga?
9. 9
Solución: 𝐼 =
𝑉
𝑅
𝐼 =
12
10
I=1.2
P= E x I
P=12 x 1.2
P=14.4 W
La potencia que suministra la carga es de 14.4 W.
13) Un resistor de 12 El circuito de una fuente lleva 0.5 A. ¿Cuántos Watts de
Ω
potencia son disipados por el resistor ¿Cuál debe ser el Wattaje del resistor para que pueda
disipar en forma de calor esta potencia sin riesgo alguno?
Solución: V=I x R
V= o.5 x 12
V= 6 V
P= E x I
P= 6 x 0.5
P= 3W
10. 10
El wattaje necesario para que el resistor pueda disipar en forma segura es de 3W.
4. Conclusiones
Finalmente concluir que, los códigos de colores son la manera en la que se pueden
representar los colores que se observan en los formatos que un computador puede
interpretar tanto en sitios web y aplicaciones de software. Ahora bien, en el código
HTML, se debe de hacer uso de la combinación de tres colores primarios, que son el rojo,
verde y azul. Por último, cada código HTML es comprendido por un numeral (“#”),
acompañado de seis letras o números, según la intensidad de los colores anteriormente
mencionados.
Para concluir con el tema del protoboard es necesario saber que es, el protoboard es
una placa en la que se pueden insertar componentes electrónicos y cables con la finalidad de
experimentar diferentes circuitos, la ventaja que este tienen y que a la hora de trabajar te sirve
su facilidad de ensamblaje es decir que no necesitas soldar si no con el simple hecho de
conectarlo. Las partes más importantes del protoboard reciben el nombre de: Canal central,
los buses y las pistas.
Con respecto a la ley de OHM podemos concluir que es una ley postulada por George
Simon Ohm, es importante recalcar que es una ley primordial o básica que nos sirve para
entender los fundamentos principales de los circuitos eléctricos. Esta ley establece o
determina que la intensidad de corriente eléctrica es directamente proporcional a la fuerza e
inversamente proporcional a la resistencia ( ), dicha fórmula es necesaria para el
𝐼 =
𝐸
𝑅
desarrollo de los diversos problemas que se nos plantearon anteriormente.
11. 11
Para finalizar podemos decir que, para resolver los diferentes problemas es necesario
aplicar la ley de watt que dice que la potencia eléctrica es directamente proporcional a la
fuerza y la intensidad que la recorre, teniendo en cuenta la fórmula P=E x I que es
primordial para resolver cualquier problema.
5. Blogs del curso
https://tecnofutuo.blogspot.com/
https://laurasofiatic.blogspot.com/
https://tecnosleon.blogspot.com/
https://tecnosleon.blogspot.com/p/periodo-2-2021.html
https://ariasvance.blogspot.com/
6. Evidencias de trabajo