Phantom 4 Pro V2.0 by SZ DJI TECHNOLOGY CO., LTD: FCC ID SS3-GL300L1801 Deep Dive – Features, Wireless Specs & Internal Teardown

Introduction

The Phantom 4 Pro V2.0 from SZ DJI TECHNOLOGY CO., LTD represents a benchmark in the evolution of smart prosumer drones, combining advanced imaging, robust wireless communication, and intelligent flight control. Engineered as a high-performance flying camera, this model is tailored for creators and professionals seeking exceptional image quality and operational reliability. A standout feature is its FCC certification under ID SS3-GL300L1801, which not only authorizes legal sale and use in the United States but also assures compliance with stringent RF emission and interference standards.

This article delivers a comprehensive analysis of the Phantom 4 Pro V2.0, focusing on its key specifications, wireless technologies, internal hardware, and regulatory insights. We’ll dissect the device’s core features, examine its frequency operation and wireless capabilities, and provide an expert teardown analysis based on internal component photographs. Whether you’re an engineer, tech enthusiast, or drone aficionado, this deep dive uncovers what sets the Phantom 4 Pro V2.0 apart in the competitive UAV landscape.

Key Features & Specifications

The Phantom 4 Pro V2.0 is engineered for users demanding professional-grade performance in aerial imaging and drone control. Its features are purpose-built to deliver both creative flexibility and operational reliability.

Key Features

• Remote Controller with Extended Range

• Transmission range up to 4.3 miles (7 km), providing exceptional operational freedom and flexibility for various shooting scenarios.

• Comprehensive Physical Controls

• The remote controller is equipped with dedicated physical buttons and dials for exposure adjustment, camera tilt, photo capture, and video recording. This tactile feedback enables precise, on-the-fly adjustments without relying solely on touchscreen inputs.

• Advanced Camera System

• 1-inch CMOS sensor delivers superior dynamic range and low-light performance, critical for professional imaging.
• Capable of recording 4K video at 60 fps and at up to 100 Mbps, ensuring cinematic quality and crisp detail even in fast-moving scenes.

• Supports 20 megapixel stills, ideal for high-resolution photography.

• Dual Frequency HD Video Downlink

• The controller supports both 2.4 GHz and 5.8 GHz bands, optimizing real-time video transmission and minimizing interference, which is vital for consistent FPV (First Person View) and control.

• Integrated Internal Battery

• The remote controller features a built-in battery, simplifying power management and extending operational sessions.

• Noise Reduction Technology

• Advanced engineering has reduced power noise by 60% and overall noise by 4 dB, contributing to quieter operation—a significant advantage for both audio-sensitive video shoots and wildlife observation.

• Smart Prosumer Flying Camera

• Equipped with intelligent obstacle avoidance and subject tracking, the Phantom 4 Pro V2.0 is designed to fly safely and autonomously in complex environments.

Technical Specifications

• Sensor: 1-inch CMOS, 20 MP stills
• Video: 4K at 60fps, 100 Mbps bitrate
• Remote Controller Range: Up to 4.3 mi (7 km)
• Wireless: Dual frequency (2.4GHz/5.8GHz), Bluetooth present (details unspecified)
• Noise Reduction: 60% power noise reduction, 4 dB overall noise reduction

These features, drawn from the user manual and technical documentation, underscore the Phantom 4 Pro V2.0’s status as a top-tier tool for aerial imaging. The combination of a large sensor, high bitrate video, robust wireless range, and refined physical controls caters to demanding creative and operational needs.

Operating Frequencies

The Phantom 4 Pro V2.0, as certified under FCC ID SS3-GL300L1801, operates across multiple frequency bands. These bands are critical for its wireless control, video transmission, and other RF-based functionalities.

Significance:
– The use of both 2.4 GHz and 5.8 GHz bands enables flexible, interference-resistant communication for command/control and HD video downlink.
– Output power levels are optimized for strong, reliable connections while meeting FCC emission limits.
– These frequency allocations support dual-band operation, a hallmark of DJI’s robust wireless ecosystem.

Technology Deep Dive

The Phantom 4 Pro V2.0 leverages a sophisticated suite of wireless technologies, primarily operating on the 2.4 GHz and 5.8 GHz bands. These are the same frequency ranges commonly used for Wi-Fi and Bluetooth, but DJI employs proprietary protocols to ensure low-latency, high-reliability links for both control and HD video streaming.

Bluetooth is present, likely used for device pairing or auxiliary functions, though specific implementation details are not disclosed in the documentation.

By utilizing dual frequency operation, the Phantom 4 Pro V2.0 can dynamically switch between bands to avoid interference and maintain robust connections, even in congested RF environments. The selected output power levels strike a balance between extended range (up to 4.3 miles) and compliance with regulatory power limits, minimizing the risk of interference with other devices.

The internal design, as confirmed by test reports, features substantial RF shielding and careful PCB layout to ensure electromagnetic compatibility (EMC). This not only enhances performance in challenging environments but also ensures the device meets strict FCC standards for unintentional emissions and susceptibility.

Overall, the integration of advanced RF design, dual-band operation, and noise mitigation technologies enables the Phantom 4 Pro V2.0 to deliver reliable, high-quality wireless performance—crucial for demanding aerial imaging applications.

In-Depth Internal Component Analysis / Teardown

A closer look at the Phantom 4 Pro V2.0’s internal hardware provides valuable insight into DJI’s engineering prowess. Below, we analyze detailed internal component photographs, highlighting key elements and their contributions to performance and reliability.

The partially disassembled remote controller reveals a high-density PCB housed within a robust plastic shell. Central to the design is a prominent integrated circuit, likely serving as the main microcontroller or RF transceiver, surrounded by supporting ICs for power management and signal conditioning. The presence of a removed metal shield indicates a dedicated RF or sensitive analog section, essential for maintaining low-latency, interference-resistant communication in both 2.4 GHz and 5.8 GHz bands. The PCB features an ENIG finish, multiple ground points, and a complex multi-layer structure—hallmarks of a design focused on signal integrity and EMI suppression. Antenna feedlines, power connectors, and USB interfaces are strategically positioned for modularity and serviceability. Overall, the construction reflects a commitment to high performance, with careful attention to RF shielding, power regulation, and mechanical robustness.

With the remote controller fully opened, the densely populated main PCB and electromechanical assemblies are clearly visible. Key integrated circuits, including the main SoC, RF transceivers, and memory chips, are strategically placed near antenna connectors and shielded regions to optimize wireless performance. The dual external antennas, connected via coaxial cables, underscore the importance of robust, multi-band communication. Joystick and gimbal assemblies, equipped with potentiometers or Hall sensors, provide high-precision control feedback. The presence of multiple FPC/FFC connectors and a substantial battery pack highlights a modular approach to assembly and maintenance. Extensive ground stitching, controlled impedance routing, and meticulous component placement reflect a design optimized for EMI/RFI resilience and reliable high-speed data handling.

The comprehensive teardown layout showcases the modular architecture of the Phantom 4 Pro V2.0’s remote controller. The main PCB, populated with a mix of BGA and QFP-packaged ICs, is engineered for high-performance processing and wireless communication. The presence of a copper-shielded sub-board suggests a dedicated RF front-end or power amplification module. Power regulation is achieved through large inductors and capacitors, ensuring clean supply across analog, digital, and RF domains. Multiple connectors and ribbon cables facilitate integration of buttons, sensors, and the battery interface. The use of several shield cans, differential pair routing, and extensive ground pours demonstrates a sophisticated approach to minimizing EMI and ensuring signal fidelity. The separation of RF, power, and control circuitry is evident, underscoring DJI’s focus on reliability and serviceability in professional-grade equipment.

A close-up of a small internal component, likely a sensor or actuator module, reveals a compact black PCB with several white wires attached for signal and power transmission. The component’s central aperture and mounting holes suggest an optical or position sensor, possibly used in gimbal stabilization or motor feedback. The absence of visible ICs and minimal routing indicate a low-power, single- or double-layer board designed for reliability and ease of replacement. The robust mechanical design, including strain-relieved wiring and secure mounting points, aligns with the demands of high-vibration drone environments. This peripheral module exemplifies DJI’s modular engineering approach, enabling targeted maintenance or upgrades without affecting core system integrity.

This small, simplistic PCB is likely part of a sensor interface or mounting assembly. Lacking visible integrated circuits or complex passive components, the board features a central and two smaller mounting holes, with attached wires for low-power signal or sensor connections. The minimal routing and absence of antennas or shielding suggest a straightforward role—possibly as a bracket for an optical or magnetic sensor, or as a basic interconnect. The utilitarian design highlights DJI’s use of specialized, purpose-driven subassemblies to support the overall functionality of the drone and its controller.

A small PCB featuring a mounted sensor or encoder, this component is characterized by a central aperture and three soldered pins, indicating its likely function as a position or rotation sensor. The green FR4 board is simply routed, with a single mounting hole and three color-coded wires providing power, ground, and signal. Strain relief via adhesive ensures reliability in dynamic environments. The straightforward construction and lack of shielding or complex circuitry suggest its use in low-frequency sensing applications, such as gimbal or motor position feedback—critical for precise stabilization and control in drone operation.

This close-up reveals an octagonal PCB-based antenna module, distinguished by its flat flexible cable (FPC) connection and lack of active components. The geometry and mounting holes indicate a patch antenna, likely used for GPS or other RF applications. The FPC interface allows flexible placement within the drone’s compact internal architecture, minimizing signal loss and facilitating assembly. The absence of shielding or complex routing confirms its role as a passive element, with signal processing handled by the main PCB. This antenna module is a vital component for reliable navigation and communication, reflecting DJI’s commitment to RF performance and mechanical stability.

Regulatory Insights & FCC Filing

The FCC ID SS3-GL300L1801 is a mark of the Phantom 4 Pro V2.0’s compliance with United States regulations governing electromagnetic interference (EMI) and radiofrequency (RF) emissions. This certification, registered with the FCC, signifies that the device meets strict technical standards for safe and legal operation within the US market.

FCC filings for this device encompass a range of technical documentation, including test reports for RF exposure and electromagnetic compatibility (EMC), internal and external photographs, user manuals, and engineering block diagrams. Through rigorous laboratory testing, the Phantom 4 Pro V2.0 demonstrated adherence to FCC emission limits, ensuring it does not interfere with other wireless devices or systems.

Insights from the filing documentation reveal that the device is designed as a smart prosumer flying camera, featuring advanced imaging, obstacle avoidance, and enhanced noise reduction. The remote controller’s long-range transmission, dual-band operation, and robust shielding are all highlighted as key factors in meeting regulatory requirements. The inclusion of detailed internal photographs and user guides in the FCC filing further illustrates DJI’s commitment to transparency and engineering excellence, providing assurance to both regulators and end users.

Potential Use Cases & Target Audience

The Phantom 4 Pro V2.0’s feature set and engineering make it an ideal choice for a range of demanding aerial imaging scenarios:

• Professional Content Creation

• Cinematographers, photographers, and media production teams benefit from the drone’s 1-inch CMOS sensor and 4K/60fps video, enabling the capture of high-resolution, broadcast-quality footage with unprecedented clarity and detail.

• Surveying, Mapping, and Inspection

• Engineers and surveyors leverage the drone’s long-range, stable transmission and intelligent flight modes for efficient, accurate aerial mapping, infrastructure inspection, and environmental monitoring, even in complex or remote environments.

• Event Coverage and Real Estate

• Real estate professionals and event organizers use the Phantom 4 Pro V2.0 to generate immersive aerial tours and promotional videos, taking advantage of its smooth tracking, obstacle avoidance, and easy-to-use control system.

With its combination of intelligent flight features, professional imaging, and robust wireless performance, the Phantom 4 Pro V2.0 is positioned as a versatile tool for creators, professionals, and advanced hobbyists seeking uncompromising results.

Conclusion

The Phantom 4 Pro V2.0 by SZ DJI TECHNOLOGY CO., LTD stands as a flagship example of professional UAV engineering, offering a blend of advanced imaging, intelligent flight control, and robust wireless communication. Its FCC certification (ID: SS3-GL300L1801) guarantees not only regulatory compliance but also a level of technical excellence that meets the demands of both creative and industrial users. With its modular, high-quality internal architecture and industry-leading features, the Phantom 4 Pro V2.0 continues to set the standard for smart prosumer drones—delivering reliable, high-performance aerial imaging for a new era of creators and professionals.

Related Documents

• Users Manual
• Int Photos
• Ext Photos
• Fcc Id Label