QED Info Thread.

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I have just bought one second hand and so far so good, not too hard to use,nice and light and there is plenty of support...
G, day. I see it advertised with a power bank battery. Is that a set up like a gpx where the battery is connected by a lead?
 
I reckon ChatGPT - GPT-4 could help resolve this issue. I can help if needed use the AI to find the solution. Inbox if needed.
I'm curious to know if anyone has any comparisons over targets of gold comparing SIMPLEX+, QED PL4 & GPX6000, GPX7000 (I want to see all 4 go the same targets lol. I owned a PL2 gave it away after finding bottlecaps in a couple months now considering getting another one but concerned about this auto ground tracking comment I just saw.
You might do better to take your ground balancing idea straight to the experts:
https://www.qedmetaldetectors.com.au/
 
Nah I can't be bothered mate to be honest. Surely he's here to see this the owner or someone else can tell him haha.

CHAT GPT QED IMPROVEMENT RESPONSES:
Incorporating an auto-tracking function in the custom PI metal detector would involve integrating a GPS module and software that can automatically log and track the user's movements, locations, and finds during detecting sessions. Here's a step-by-step approach to implementing this feature:

  1. GPS module integration: Integrate a GPS module into the detector's hardware design, ensuring it has a clear line of sight to the sky for optimal GPS signal reception. Choose a GPS module with high sensitivity, fast time-to-first-fix, and low power consumption.
  2. GPS data processing: Develop software that processes the GPS data, including latitude, longitude, altitude, and time information. This software should filter and smooth the data to account for GPS inaccuracies and provide real-time location updates.
  3. Auto-tracking functionality: Implement an auto-tracking feature in the software that automatically logs the user's location at regular intervals or based on a specific distance threshold. This feature should be customizable, allowing users to enable or disable it and adjust tracking settings as needed.
  4. Visual representation: Incorporate a mapping component within the user interface, displaying the user's current location, track, and waypoints on a map. This can be achieved by integrating an existing mapping library or developing a custom mapping solution.
  5. Waypoints and finds logging: Allow users to manually add waypoints or automatically log finds with their corresponding GPS coordinates. This feature can be complemented by the option to add notes, photos, or other metadata to each find.
  6. Export and import functionality: Provide the option to export tracking data, waypoints, and finds to common file formats (e.g., GPX, KML, or CSV) for easy sharing, backup, and further analysis. Additionally, offer the ability to import previously logged data for continued use or reference during future detecting sessions.
  7. Battery management: Optimize power consumption to minimize the impact of GPS tracking on battery life. Implement power-saving modes, such as adaptive tracking frequency or turning off the GPS module when not in use.
It's also possible to implement auto tracking functionality through a Bluetooth connection to a smartphone app. This can be a cost-effective solution compared to integrating GPS tracking hardware into the metal detector. COST EFFECTIVE IDEA

Here's how it could work:

  1. The metal detector would need to have a built-in Bluetooth module and a smartphone app would need to be developed that can communicate with the detector over Bluetooth.
  2. The app would have an auto-tracking function that continuously scans the ground and provides real-time data on the app's display.
  3. The app could have a simple user interface that allows the user to adjust the auto-tracking settings to optimize the detector's performance for specific ground conditions.
  4. The app could also include features such as target identification, depth estimation, and audio alerts to notify the user when a potential target has been detected.
Overall, a Bluetooth-based auto-tracking function would provide a cost-effective solution for users who want to improve their metal detecting performance without having to invest in a dedicated GPS tracking system.

Brainstorming in depth more:

Sure, here's a step-by-step guide on how to implement Bluetooth connectivity with a push-to-hold button:

  1. Choose a Bluetooth module: First, you'll need to choose a Bluetooth module that fits your needs. Some popular options are the HC-05 and HC-06 modules. These modules allow for serial communication between the metal detector and a smartphone app.
  2. Connect the Bluetooth module to the metal detector: Once you have your Bluetooth module, you'll need to connect it to your metal detector's microcontroller. Most Bluetooth modules have a serial interface that can be connected to the metal detector's UART.
  3. Write the firmware: You'll need to write the firmware for the metal detector's microcontroller to enable Bluetooth connectivity. This firmware will need to handle communication with the Bluetooth module and translate the metal detector's signals into a format that can be sent over Bluetooth.
  4. Create a smartphone app: Next, you'll need to create a smartphone app that can receive data from the metal detector over Bluetooth. This app will need to be able to connect to the metal detector, display the metal detector's readings, and provide any other features you want to include.
  5. Pair the metal detector and smartphone: To connect the metal detector and smartphone, you'll need to pair them using Bluetooth. To do this, you can create a push-to-hold button that puts the metal detector into pairing mode. When the metal detector is in pairing mode, the smartphone app can detect it and connect to it.
  6. Add a double-click function to disconnect: Once the metal detector and smartphone are connected, you can add a double-click function to disconnect. This can be done by programming the firmware to detect a double-click and send a signal to the smartphone app to disconnect.
Overall, this implementation will require some knowledge of programming and electronics, but it's definitely possible to create a cost-effective Bluetooth-enabled metal detector.
Wrong type of tracking buddy.

They are talking about ground tracking i.e. auto adjustments of the detector ground tracking to changes in the ground mineralisation.
 
Nah I can't be bothered mate to be honest. Surely he's here to see this the owner or someone else can tell him haha.

CHAT GPT QED IMPROVEMENT RESPONSES:
Incorporating an auto-tracking function in the custom PI metal detector would involve integrating a GPS module and software that can automatically log and track the user's movements, locations, and finds during detecting sessions. Here's a step-by-step approach to implementing this feature:

  1. GPS module integration: Integrate a GPS module into the detector's hardware design, ensuring it has a clear line of sight to the sky for optimal GPS signal reception. Choose a GPS module with high sensitivity, fast time-to-first-fix, and low power consumption.
  2. GPS data processing: Develop software that processes the GPS data, including latitude, longitude, altitude, and time information. This software should filter and smooth the data to account for GPS inaccuracies and provide real-time location updates.
  3. Auto-tracking functionality: Implement an auto-tracking feature in the software that automatically logs the user's location at regular intervals or based on a specific distance threshold. This feature should be customizable, allowing users to enable or disable it and adjust tracking settings as needed.
  4. Visual representation: Incorporate a mapping component within the user interface, displaying the user's current location, track, and waypoints on a map. This can be achieved by integrating an existing mapping library or developing a custom mapping solution.
  5. Waypoints and finds logging: Allow users to manually add waypoints or automatically log finds with their corresponding GPS coordinates. This feature can be complemented by the option to add notes, photos, or other metadata to each find.
  6. Export and import functionality: Provide the option to export tracking data, waypoints, and finds to common file formats (e.g., GPX, KML, or CSV) for easy sharing, backup, and further analysis. Additionally, offer the ability to import previously logged data for continued use or reference during future detecting sessions.
  7. Battery management: Optimize power consumption to minimize the impact of GPS tracking on battery life. Implement power-saving modes, such as adaptive tracking frequency or turning off the GPS module when not in use.
It's also possible to implement auto tracking functionality through a Bluetooth connection to a smartphone app. This can be a cost-effective solution compared to integrating GPS tracking hardware into the metal detector. COST EFFECTIVE IDEA

Here's how it could work:

  1. The metal detector would need to have a built-in Bluetooth module and a smartphone app would need to be developed that can communicate with the detector over Bluetooth.
  2. The app would have an auto-tracking function that continuously scans the ground and provides real-time data on the app's display.
  3. The app could have a simple user interface that allows the user to adjust the auto-tracking settings to optimize the detector's performance for specific ground conditions.
  4. The app could also include features such as target identification, depth estimation, and audio alerts to notify the user when a potential target has been detected.
Overall, a Bluetooth-based auto-tracking function would provide a cost-effective solution for users who want to improve their metal detecting performance without having to invest in a dedicated GPS tracking system.

Brainstorming in depth more:

Sure, here's a step-by-step guide on how to implement Bluetooth connectivity with a push-to-hold button:

  1. Choose a Bluetooth module: First, you'll need to choose a Bluetooth module that fits your needs. Some popular options are the HC-05 and HC-06 modules. These modules allow for serial communication between the metal detector and a smartphone app.
  2. Connect the Bluetooth module to the metal detector: Once you have your Bluetooth module, you'll need to connect it to your metal detector's microcontroller. Most Bluetooth modules have a serial interface that can be connected to the metal detector's UART.
  3. Write the firmware: You'll need to write the firmware for the metal detector's microcontroller to enable Bluetooth connectivity. This firmware will need to handle communication with the Bluetooth module and translate the metal detector's signals into a format that can be sent over Bluetooth.
  4. Create a smartphone app: Next, you'll need to create a smartphone app that can receive data from the metal detector over Bluetooth. This app will need to be able to connect to the metal detector, display the metal detector's readings, and provide any other features you want to include.
  5. Pair the metal detector and smartphone: To connect the metal detector and smartphone, you'll need to pair them using Bluetooth. To do this, you can create a push-to-hold button that puts the metal detector into pairing mode. When the metal detector is in pairing mode, the smartphone app can detect it and connect to it.
  6. Add a double-click function to disconnect: Once the metal detector and smartphone are connected, you can add a double-click function to disconnect. This can be done by programming the firmware to detect a double-click and send a signal to the smartphone app to disconnect.
Overall, this implementation will require some knowledge of programming and electronics, but it's definitely possible to create a cost-effective Bluetooth-enabled metal detector.
Simply attach with a good lead and jobs done. Is also hands free ;):rolleyes:😂

Tracker.jpg
 
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