Sony Imx519 Datasheet 🆕 Official

From a 2025 perspective, the IMX519 datasheet reads as a document of intelligent trade-offs. It was never designed to beat the Sony IMX378 (1.55µm pixels) in pure low-light sensitivity, nor the IMX400 (with DRAM layer) in extreme slow motion. Instead, its genius was balance . It offered 80% of the flagship speed at 60% of the power and cost.

If one were to highlight a single line from the IMX519 datasheet that changed smartphone design, it would be the . The sensor supports 60 frames per second (fps) at full 16MP resolution. To put this in perspective, its predecessor, the IMX398, typically maxed out at 30fps. This doubling of speed is achieved via a high-speed digital interface (likely MIPI CSI-2 with multiple lanes) and a redesigned column-parallel ADC architecture.

The Sony IMX519 datasheet is more than a technical manual; it is a blueprint for democratizing high-speed photography. By prioritizing readout speed and dynamic range over raw pixel size, Sony delivered a sensor that allowed OnePlus, Google, and Xiaomi to offer near-flagship performance without the flagship bill of materials. For the hardware engineer, it is a study in elegant compromise. For the historian, it marks the moment when sensor speed eclipsed sensor resolution as the primary battlefield in mobile imaging. And for the rest of us, it is the reason why a mid-range phone in 2018 could capture a split-second reaction at 60fps—a fleeting moment, frozen in silicon. sony imx519 datasheet

No datasheet is complete without the timing diagrams and power sequencing tables. The IMX519 datasheet details four primary operating modes: Preview (low-res, low power), Still Capture (16MP, high power), Video (4K at 30fps), and Slow Motion (720p at 480fps). The power consumption curve is revealing: the sensor draws a modest 180mW during 1080p video recording but spikes to nearly 400mW during sustained 480fps burst modes. This explains why early IMX519-equipped phones often limited slow-motion recordings to short 30-second bursts—a direct consequence of thermal dissipation limits outlined in the datasheet’s absolute maximum ratings.

Where competitors used two separate exposures (short and long) in software, leading to ghosting with moving subjects, the IMX519’s DCG allowed a single exposure to capture both highlights and shadows. For the engineer reading the datasheet, this is the moment the sensor transforms from a commodity part into a sophisticated optical instrument. From a 2025 perspective, the IMX519 datasheet reads

Scrolling further into the datasheet’s analog characteristics reveals the presence of . This is the sensor’s secret weapon. In low light, the sensor operates in High Conversion Gain (HCG) mode, where the floating diffusion capacitor is small, amplifying the signal from the photodiode to overcome read noise. In bright light, it switches to Low Conversion Gain (LCG), using a larger capacitor to prevent saturation. The datasheet shows that this switching can happen on a per-row basis, effectively creating a native, hardware-level HDR (High Dynamic Range) stream.

The 1.22µm pitch is a balance; it is small enough to fit a 16MP resolution in a compact module but large enough to avoid the diffraction and noise issues that plagued the 0.9µm pixels of the era. The datasheet’s quantum efficiency graphs imply that while light gathering was not industry-leading, the sensor’s deep trench isolation (DTI) minimized crosstalk between pixels, preserving color fidelity in low light. It offered 80% of the flagship speed at

This specification had two profound real-world implications. First, it enabled at full resolution, allowing devices to capture a buffer of 16MP images before the user even pressed the shutter. Second, and more importantly, it made high-frame-rate video accessible. The datasheet confirms 720p at 480fps and 1080p at 120fps. For a mid-range sensor in 2017, this was unprecedented. It democratized slow-motion videography, moving it from a niche feature to a mainstream tool.