OnePlus will hold a new product launch event on March 24 to officially launch a new generation of the annual flagship OnePlus 9 series.
OnePlus officially announced the real shots of the OnePlus 9 Pro for the first time, and revealed that the phone will use the industry’s first diffuse reflection gradient texture, which combines matte and mirror effects to bring more temperament, higher-end, and highly textured body texture.
According to the introduction from the Industrial Design Director of OnePlus, the design of the OnePlus 9 series is inspired by the Maison&Object Paris Fashion Design Exhibition in 2018, warm minimalism has injected some inspiration into the tone of the OnePlus 9 series.
He stated that the design concept of the OnePlus 9 series is to reshape reality. They hope to use a more pure and concise design to bring users a more peaceful, natural, and authentic feeling. Especially in the use of light, color, and material, the product returns to a true and pure state, thus becoming both elegant and powerful.
It can be seen from the official picture of the real phone that the back of the OnePlus 9 series not only has the excellent hand feeling of frosted craftsmanship but also retains the reflective effect of the mirror glass visually. The fusion of the matte surface and the mirror surface brings an excellent experience in hand and sight feel.
It is worth mentioning that the real phone picture released by OnePlus this time also officially announced the screen design of the OnePlus 9 Pro. According to the picture, the phone still continues the curved dot screen scheme of the previous generation, and the front camera is located on the upper left corner of the screen.
According to previous news, the OnePlus 9 Pro will use the latest LTPO screen technology, which can realize 5~120Hz intelligent refresh rate adjustment, and it also has 2K+ level resolution, supports 1 billion color display, which can bring very excellent display effect. It can also perfectly display the color of the image taken by the Hasselblad imaging system at the same time.