Leaked iPhone 15 design, said to have a titanium frame, rounded back with curved back edges
The iPhone 15 – the purported successor to the iPhone 14 – could feature a new bezel design compared to previous models. According to a new leak, Apple will consider significant design changes for the next-generation iPhone model. The iPhone 15 is said to come with reverse curved sides instead of flat like on the iPhone 14 series. The Cupertino giant may also use titanium instead of stainless steel with the iPhone 15. Pro models in the upcoming series may have a titanium frame, while the iPhone 15 and iPhone 15 Plus may have a stainless steel frame.
Tipster TomApplePro on Twitter declare that the iPhone 15 can adopt the new border design. According to him, the end of the rear edges of the upcoming phone will be curved instead of square edges like the previous generation. iPhone 12″, iPhone 13″and iPhone 14″ model. Furthermore, Apple is expected to use titanium with the iPhone 15, unlike previous models with stainless chassis, including iPhone 14 Pro lined up.
Since the new material is more expensive than stainless steel, Apple could adopt a titanium frame on the high-end iPhone 15 Pro and iPhone 15 Ultra models. The regular iPhone 15 and iPhone 15 Plus are rumored to come with a stainless steel frame.
Apple’s 2023 iPhone family is expected includes the regular iPhone 15, iPhone 15 Pro, and iPhone 15 Pro Max models. The iPhone 15 Pro and iPhone 15 Pro Max are said to be equipped with Apple’s next-generation A17 Bionic chip and 8GB of RAM. Non-Pro models could be equipped with this year’s A16 Bionic chip.
Earlier TF International Securities analyst Ming-Chi Kuo stated that the buttonless design and support for USB type-C charging will be the main highlights of the iPhone 15 lineup. The high-end models in the iPhone 15 series are said to have hard buttons instead of physical power and volume buttons. similar to the home button on the iPhone 7, iPhone 8, and iPhone SE. They can be equipped with three Taptic Engine vibration motors to simulate the sensation of clicking.