**Educational Content: Analysis of Points in a Uniform Electric Field****Text Description:**The image illustrates two points, A and B, situated within a uniform electric field. The points are separated by a vertical distance of 3 cm and a horizontal distance of 7 cm. The electric field has a magnitude of 1000 V/m and is oriented to the right.**Figure Explanation:**- **Points A and B:** - Point A is positioned above point B, with a vertical separation of 3 cm. - The horizontal distance between points A and B is 7 cm.- **Electric Field:** - Represented by arrows pointing to the right, indicating the direction of the field. - The magnitude of the electric field is given as \( E = 1000 \, \text{V/m} \).This visual representation helps in understanding the configuration of points within an electric field, crucial for analyzing electric potential differences and field effects. **Question:**What is the potential difference between point A and point B?**Interface Explanation:**- **Input Box for Answer:** You need to calculate or provide the potential difference, denoted as ΔV, between the two points mentioned and enter the value in the provided input box.- **Buttons Overview:** - **Formatting Buttons:** The interface includes two buttons for mathematical formatting. The first button represents mathematical operations (e.g., square roots), while the second is for inserting symbols (e.g., Δ, Φ). - **Undo/Redo Buttons:** Allows you to undo or redo your actions. - **Reset Button:** Resets the input field to its original state. - **Virtual Keyboard Button:** Opens an on-screen keyboard for input. - **Help Button:** Provides assistance or additional information if needed.- **Units:** The answer should be entered in volts (V), as indicated to the right of the input box.

Potential difference = E * dx E = 1000V/m dx = 7cm = 0.07 m

The picture below shows two points A and B which are located in a uniform electric field. Points A and B are separated by 3 cm vertically and 7 cm horizontally. The electric field is 1000 V/m and points to the right. (Figure 1)

The picture below shows two points A and B which are located in a uniform electric field. Points A and B are separated by 3 cm vertically and 7 cm horizontally. The electric field is 1000 V/m and points to the right. (Figure 1)

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**Educational Content: Analysis of Points in a Uniform Electric Field**

**Text Description:**

The image illustrates two points, A and B, situated within a uniform electric field. The points are separated by a vertical distance of 3 cm and a horizontal distance of 7 cm. The electric field has a magnitude of 1000 V/m and is oriented to the right.

**Figure Explanation:**

- **Points A and B:**
- Point A is positioned above point B, with a vertical separation of 3 cm.
- The horizontal distance between points A and B is 7 cm.

- **Electric Field:**
- Represented by arrows pointing to the right, indicating the direction of the field.
- The magnitude of the electric field is given as \( E = 1000 \, \text{V/m} \).

This visual representation helps in understanding the configuration of points within an electric field, crucial for analyzing electric potential differences and field effects.

**Question:**
What is the potential difference between point A and point B?

**Interface Explanation:**

- **Input Box for Answer:** You need to calculate or provide the potential difference, denoted as ΔV, between the two points mentioned and enter the value in the provided input box.

- **Buttons Overview:**
- **Formatting Buttons:** The interface includes two buttons for mathematical formatting. The first button represents mathematical operations (e.g., square roots), while the second is for inserting symbols (e.g., Δ, Φ).
- **Undo/Redo Buttons:** Allows you to undo or redo your actions.
- **Reset Button:** Resets the input field to its original state.
- **Virtual Keyboard Button:** Opens an on-screen keyboard for input.
- **Help Button:** Provides assistance or additional information if needed.

- **Units:** The answer should be entered in volts (V), as indicated to the right of the input box.

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