DJI Goggles by SZ DJI TECHNOLOGY CO., LTD. (Model: G1S1612, FCC ID SS3-G1S1612): In-Depth Teardown, Specs, and Regulatory Analysis

Introduction

The DJI Goggles by SZ DJI TECHNOLOGY CO., LTD. (Model: G1S1612) are engineered to deliver an immersive First Person View (FPV) experience, primarily for users of DJI aircraft. Designed with high-performance displays, intuitive controls, and seamless connectivity, these goggles transform aerial operations and HD video consumption alike. With FCC certification under the identifier SS3-G1S1612, the DJI Goggles have undergone rigorous testing to ensure compliance with US radio frequency emission standards—an essential prerequisite for legal sale and operation within the United States.

This article offers an expert-level breakdown of the DJI Goggles, focusing on their key features, technical specifications, wireless technologies, and internal hardware. We’ll also explore the device’s regulatory journey through the FCC, providing insights into what this means for users and the broader marketplace. Whether you’re an FPV enthusiast, a drone pilot, or simply intrigued by high-end wearable tech, read on to discover what sets the DJI Goggles apart.

Key Features & Specifications

The DJI Goggles (Model: G1S1612) stand out for their blend of advanced display technology, ergonomic design, and robust connectivity options. Below, we distill their most noteworthy features and technical specifications, highlighting the practical advantages for end users.

Key Features

• Real-Time FPV with DJI Aircraft
  Experience ultra-low latency video transmission directly from your DJI drone, enabling precise maneuvering and immersive aerial navigation.
• High-Performance Displays
  Dual 5-inch screens offer crisp, vibrant visuals, maximizing the immersive effect for both FPV flight and HD video playback.
• Intelligent Flight Mode Compatibility
  Supports DJI’s signature Intelligent Flight Modes—including TapFly, ActiveTrack, Terrain Follow, and Tripod—allowing users to leverage advanced automation and tracking directly from the goggles interface.
• Comprehensive Input Interfaces
  Multiple ports (Micro USB, HDMI, audio jack, and Micro SD card slot) ensure flexible connectivity for data transfer, external video sources, audio output, and storage expansion.
• Intuitive Touch Panel Operation
  The right-hand touch panel provides streamlined, one-handed control for menu navigation, playback, and flight adjustments.
• Firmware Upgrade Support
  Easily update device firmware via DJI Assistant 2, ensuring compatibility and access to the latest features.
• HD Video Playback
  Enjoy high-definition video playback directly through the goggles, ideal for immersive media consumption beyond FPV flying.

Technical Specifications

• Weight:
• Lenses: 490 g
• Strap: 520 g
• Battery:
• Capacity: 9440 mAh
• Energy: 35.44 Wh
• Max Operating Time: 6 hours
• Sensors:
• Gyroscope
• Accelerometer
• Proximity sensor
• Display:
• Screen Size: 5 inch × 2
• Operating Temperature Range:
• 32°F (0°C) – 104°F (40°C)
• Operating Frequency:
• 2.4 GHz (Wi-Fi)
• Max Transmission Distance:
• Matches the connected DJI aircraft
• Wireless:
• Wi-Fi: 2.4 GHz
• Bluetooth: Present (details not specified)
• Input/Output:
• Micro USB, HDMI, 3.5mm audio jack, Micro SD card slot

Benefits and User Impact

These specifications translate into a wearable device capable of extended use in diverse environments, with high-resolution displays and a battery designed for long sessions. The inclusion of multiple sensors not only enhances flight interactivity—such as head tracking—but also ensures a responsive and safe user experience. Modular connectivity and straightforward firmware updates further future-proof the goggles, making them adaptable to both evolving DJI platforms and user needs.

Operating Frequencies

The wireless capabilities of the DJI Goggles (FCC ID SS3-G1S1612) are defined by the following frequency ranges and output power levels, as reported in their FCC filing:

These frequency bands are pivotal in shaping the device’s wireless performance, range, and compliance with regulatory standards. The primary 2.4 GHz band is commonly used for Wi-Fi and Bluetooth communications, balancing range and throughput while minimizing interference with other RF devices. The specified output power levels ensure effective communication without exceeding FCC-mandated emission limits, safeguarding both user experience and spectrum integrity.

Technology Deep Dive

At the heart of the DJI Goggles’ wireless operation is the 2.4 GHz frequency band, a mainstay for consumer wireless technologies such as Wi-Fi and Bluetooth. The device leverages this spectrum to facilitate robust, low-latency video transmission from DJI aircraft, as well as seamless communication with companion devices. Bluetooth support, while present, is not detailed in the current documentation but likely serves for auxiliary device pairing or control.

Operating within the 2.4 GHz band offers several advantages:
– Performance & Range: The band is well-suited for reliable medium-range communication, enabling the goggles to maintain a strong link with the drone or other peripherals across typical operational distances.
– Interference Management: By adhering to FCC power output limits and employing advanced modulation schemes, the device minimizes susceptibility to interference from other 2.4 GHz equipment (e.g., routers, wireless cameras).
– Power Efficiency: Optimized RF design ensures extended battery life, supporting up to 6 hours of continuous use—crucial for field operations and immersive sessions.

The FCC test documentation underscores that the goggles’ emissions are within permissible limits, affirming both user safety and regulatory compliance. Overall, the wireless architecture is engineered for stability, responsiveness, and adaptability in demanding aerial environments.

In-Depth Internal Component Analysis / Teardown

Main Interface PCB: Modular Connectivity and Build Quality

A close examination of the internal interface PCB reveals a commitment to modularity and reliability. The board features a black soldermask over standard FR4 material, with evidence of a multilayer design—likely four or more layers—judging by the abundance of vias and the density of passive components. Dominating the layout are two large FPC/FFC connectors, strategically positioned for secure attachment to display panels or internal modules, underscoring the device’s flexible construction. A micro-USB connector suggests user-facing access for data, firmware updates, or servicing. While no major integrated circuits or RF components are present, the array of passive components and gold-plated mounting holes points to careful attention to signal integrity, grounding, and mechanical stability. The absence of EMI shielding is typical for boards not handling sensitive analog or RF signals, and the compact design further supports the goggles’ lightweight, wearable form factor.

Sensor and Auxiliary Subassembly: Modular Sensor Integration

The internal architecture also includes a pair of interconnected PCBs, joined by a flat flexible cable and featuring an additional small daughterboard or sensor module. The boards are constructed with a dark soldermask and feature gold-plated mounting holes, reinforcing robust grounding and assembly. While no significant IC markings are visible, the PCB footprints and presence of a small optical window suggest this module likely houses a sensor—potentially a camera or proximity sensor critical for head tracking or user detection. The low-to-moderate component density and absence of large power components indicate these boards serve auxiliary roles, interfacing with sensors rather than main processing or RF functions. The use of impedance-controlled traces and FFCs highlights a design optimized for high-speed or sensitive signals, essential for real-time sensor feedback in FPV applications. Overall, the modularity and build quality align with the demands of high-end wearable devices, ensuring ease of assembly, servicing, and future upgrades.

Regulatory Insights & FCC Filing

The FCC ID SS3-G1S1612 marks the DJI Goggles as fully compliant with US standards for electromagnetic interference and radio frequency emissions. This certification, registered via FCC.gov (grant date: none specified), is a legal requirement for marketing and operating wireless devices in the United States. The FCC filing process subjects the device to extensive testing—including RF exposure, electromagnetic compatibility (EMC), and spurious emission assessments—to ensure both user safety and non-interference with other spectrum users.

FCC filings also provide a wealth of technical documentation, such as user manuals, internal and external photographs, block diagrams, and test reports. According to the ‘Users-Manual-3282495.pdf’, the DJI Goggles deliver an immersive FPV experience, leveraging high-performance displays and ultra-low latency video downlink for seamless integration with DJI aircraft. Features like head tracking, intuitive touch controls, and compatibility with Intelligent Flight Modes are highlighted, reflecting both technical sophistication and user-centric design. The internal photos and test reports further confirm the device’s robust construction and adherence to regulatory limits, validating its place as a premium, legally compliant wearable for drone operators.

Potential Use Cases & Target Audience

The DJI Goggles (FCC ID SS3-G1S1612) are purpose-built for a diverse array of demanding scenarios:

• Aerial FPV Piloting for DJI Drone Users
  Drone enthusiasts and professional pilots can harness the goggles’ ultra-low latency video feed to navigate complex environments, execute cinematic shots, or conduct precise mapping missions—all from an immersive, first-person vantage point.

• Immersive HD Video Viewing
  Beyond flight, the goggles serve as a high-definition personal theater, enabling users to watch HD videos in a private, enveloping environment—ideal for media consumption at home or on the go.

• Intuitive, One-Handed Operation for Field Use
  The right-hand touch panel and modular design make the goggles exceptionally easy to operate, even during active drone sessions or in challenging outdoor conditions. This user-centric interface appeals to both seasoned pilots and newcomers seeking straightforward control.

These use cases underscore the goggles’ versatility, making them an essential tool for anyone seeking real-time aerial insight, immersive media, or hands-on drone control.

Conclusion

The DJI Goggles by SZ DJI TECHNOLOGY CO., LTD. (Model: G1S1612, FCC ID SS3-G1S1612) exemplify the convergence of advanced display technology, modular hardware design, and rigorous regulatory compliance. With their robust wireless specs, user-focused controls, and premium internal build, they stand out as a top-tier solution for FPV drone pilots and immersive video enthusiasts alike. The FCC certification not only guarantees legal operation but also attests to the device’s safety and technical excellence. As the boundaries of consumer electronics and aerial imaging continue to expand, the DJI Goggles remain at the forefront—delivering unparalleled performance, reliability, and user experience.

Related Documents

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