JERMAINE MORTON'S invention of an mechanical electronic battery powered portable machine design functional likeness as an diamond detector long ranges wirelessly The design utilizes SONIC OSCILLATOR Horn that emits thermal magnetic electrolytes vector beam TYPE ELECTROMAGNETIC HALL EFFECT TRANSCEIVER AIR COIL TYPE SOLENOID PULL PUSH SENSE DRIVEN TRANSDUCTOR MODULATED HIGH FREQUENCY PULSE THERMAL MAGNETIC DYNAMIC MICROWAVE VOLTAGE & TEMPERATURE FEEDBACK TEMPERATURE VECTOR SENSORY OR PROXIMITY BEAM FEEDBACK SENSORY DIAMOND DETECTOR subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector Subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency. Conceptual Design and Operating Principle The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification. These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants. Electromagnetic Hall Effect Integration To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone. High-Frequency Pulse and Thermal Detection Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency. Conceptual Design and Operating Principle The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification. These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants. Electromagnetic Hall Effect Integration To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone High-Frequency Pulse and Thermal Detection Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency. Conceptual Design and Operating Principle The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification. These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants Electromagnetic Hall Effect Integration To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone High-Frequency Pulse and Thermal Detection Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency Conceptual Design and Operating Principle The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification. These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants Electromagnetic Hall Effect Integration To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone High-Frequency Pulse and Thermal Detection Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors Subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton

JERMAINE MORTON'S invention of an mechanical electronic battery powered portable machine design functional likeness as an diamond detector long ranges wirelessly 
The design utilizes SONIC OSCILLATOR Horn that emits thermal magnetic electrolytes vector beam TYPE ELECTROMAGNETIC HALL EFFECT TRANSCEIVER AIR COIL TYPE SOLENOID PULL PUSH SENSE DRIVEN TRANSDUCTOR MODULATED HIGH FREQUENCY PULSE THERMAL MAGNETIC DYNAMIC MICROWAVE VOLTAGE & TEMPERATURE FEEDBACK TEMPERATURE VECTOR SENSORY OR PROXIMITY BEAM FEEDBACK SENSORY DIAMOND DETECTOR subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton 
Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector Subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency.

Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants.

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone.

High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors

Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency.

Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants.

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone

High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors
Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency.
Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone
High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors

Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency

Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone
High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors

Subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton

Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector Subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency.

Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants.

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone.

High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors

Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency.

Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants.

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone

High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors
Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency.
Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone
High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors

Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency

Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone
High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors

Subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton

 

JERMAINE MORTON'S invention of an mechanical electronic battery powered portable machine design functional likeness as an diamond detector long ranges wirelessly 
The design utilizes SONIC OSCILLATOR Horn that emits thermal magnetic electrolytes vector beam TYPE ELECTROMAGNETIC HALL EFFECT TRANSCEIVER AIR COIL TYPE SOLENOID PULL PUSH SENSE DRIVEN TRANSDUCTOR MODULATED HIGH FREQUENCY PULSE THERMAL MAGNETIC DYNAMIC MICROWAVE VOLTAGE & TEMPERATURE FEEDBACK TEMPERATURE VECTOR SENSORY OR PROXIMITY BEAM FEEDBACK SENSORY DIAMOND DETECTOR subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton 

Jermaine Morton’s Invention: The Sonic Pulse Horn wireless battery powered-long range finder Type Diamond Detector Subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency.

Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants.

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone.

High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors

Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency.

Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants.

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone

High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors
Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency.
Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone
High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors

Jermaine Morton’s Invention: The Sonic Pulse Horn-Type Diamond Detector

Jermaine Morton, a prolific inventor known for integrating advanced sensory technologies with futuristic mechanical frameworks, has engineered a groundbreaking innovation: the Diamond Detector Horn. This sophisticated device is designed to locate and identify diamond materials using an advanced multi-sensory fusion of electromagnetic, sonic, and thermal technologies. At its core, this invention is a high-frequency, horn-type sensor that merges multiple scientific principles to detect the unique electromagnetic and thermal characteristics of diamonds with precision and efficiency

Conceptual Design and Operating Principle

The Diamond Detector Horn, as conceptualized by Morton, operates through a Sonic Pulse Oscillator system embedded in a horn-shaped emitter. This structure allows concentrated propagation of sound waves in a targeted direction. When activated, the oscillator generates controlled ultrasonic pulses, which bounce off solid surfaces. Diamonds, due to their exceptional hardness and crystalline lattice, produce a distinct echo pattern and resonant frequency shift, which the system interprets for identification.

These sonic interactions are enhanced by an Electrostatic Emitter housed within the horn. This emitter charges nearby materials with a static field and reads the responsive discharge rates, as diamonds exhibit unique electrostatic interactions due to their insulating properties and dielectric constants

Electromagnetic Hall Effect Integration

To further ensure accuracy, Morton’s design incorporates an Electromagnetic Hall Effect Air Coil-Type Solenoid. This subsystem detects magnetic field variations caused by the presence of specific mineral compositions. While diamonds themselves are non-magnetic, the Hall effect solenoid provides crucial information by ruling out other metallic or magnetic stones that might mimic a diamond's appearance in simpler detectors. The push-pull solenoid system works dynamically, measuring how materials influence the magnetic field in the horn’s detection zone
High-Frequency Pulse and Thermal Detection

Morton enhances the detector’s versatility through High-Frequency Pulse Thermal Magnetic Dynamic Microwave Voltage Systems. This high-tech hybrid enables real-time analysis of temperature fluctuations, heat conductivity, and microwave dielectric absorption—all of which vary drastically between diamonds and other carbon-based or crystalline materials. By sending and receiving pulsed microwave signals and thermal vectors

Subject not limiting to additional system or structure potentiometric range design inventor Jermaine Morton