A housing for an electronic device is disclosed. The housing comprises a first component and a second component separated from the first component by a gap. The housing also includes a first molded element disposed at least partially within the gap and defining at least a portion of an interlock feature, and a second molded element disposed at least partially within the gap and mechanically engaging the interlock feature. The first component, the second component, and the second molded element form a portion of an exterior surface of the housing. A method of forming the housing is also disclosed.

An electronic device may include a housing including a front plate, a rear plate, and a side member surrounding a space formed by the front plate and the rear plate, a support member disposed in the space, at least one electronic component disposed in the space, a first non-conductive member disposed on at least a portion of the support member and on the side member, a conductive pattern at least partially disposed between the side member and the first non-conductive member, and a second non-conductive member disposed between the side member and a portion of the conductive pattern and a portion of the first non-conductive member, at least a portion of the conductive pattern may be spaced apart from the at least one electronic component by a predetermined distance, and a first inclined surface may be formed on a portion of the first non-conductive member.

An electronic device in accordance with an example embodiment of the disclosure includes a first non-conductive cover defining a first surface of the electronic device, a second non-conductive cover including a first portion defining a second surface of the electronic device, and a second portion defining one portion of a lateral surface of the electronic device, a conductive frame defining an other portion of the lateral surface of the electronic device, and an antenna module, wherein the antenna module is positioned so that the one surface is substantially perpendicular to the second surface at a position within a specified proximity to the lateral surface of the electronic device and is configured to transmit and/or receive a signal through the lateral surface.

A mobile terminal comprises a body including a first frame and a second frame slidably coupled to a rear surface of the first frame in a first direction or a second direction; a flexible display unit including a front portion located on a front surface of the body, a rear portion located on a rear surface of the body, and a side portion connecting the front portion with the rear portion and surrounding one side of the body; a plurality of reinforcing ribs protruded from a rear surface of the first frame and extended in the first direction; and a plurality of supports protruded from a front surface of the second frame and located between the respective reinforcing ribs. The mobile terminal may enhance usability and portability by varying its size.

A pressure-sensitive vibration processing method can be applied to a mobile terminal including an application processor, a pressure sensor, and a vibration motor. The method can include: in a first state of the mobile terminal, notifying directly, with the pressure sensor, the vibration motor to generate vibration, when pressure received by the pressure sensor exceeds a threshold, the first state including a state where the application processor is in sleep; and in a second state of the mobile terminal, notifying, with the pressure sensor, the application processor to control the vibration motor to generate vibration, when pressure received by the pressure sensor exceeds the threshold, the second state including a state where the application processor is awake. A timely response is therefore ensured when vibration is needed, and it can also be ensured that various vibrations are handled normally during system operation to avoid abnormal vibration feedback.

Exemplary arrangements relate to a housing part (100) for an electronic terminal such as a cell phone. The housing part is comprised of carbon fiber reinforced plastic and includes at least one conductive device such as a threaded metallic insert (110) configured for galvanic connection to the electronics that are housed within a housing of the terminal. In an exemplary arrangement the housing part includes a groove (120). The groove is filled with a conductive mass (130) which provides a galvanic connection to the exposed carbon fibers within the groove. The carbon fibers may thereby be in galvanic connection with the ground of the electronics within the housing part, which helps to suppress electronic noise which may be produced by the electronics.

A mobile terminal includes a middle frame, a fixing frame, and a cover plate. The middle frame includes a first placement slot and a second placement slot. The fixing frame is disposed in the second placement slot. The cover plate is disposed in the first placement slot. The second placement slot includes first side surfaces. The first side surfaces are provided with a plurality of first protrusions. The fixing frame includes first sidewalls. The first sidewalls are provided with a plurality of second protrusions. The first protrusions and the second protrusions are arranged to form a support structure configured to support the cover plate, and the cover plate is fixedly connected to the support structure.

An electronic device is provided. The electronic device includes a front plate, a rear plate facing away the front plate, a side member disposed to surround a space defined between the front plate and the rear plate, wherein the side member is coupled to the front plate and the rear plate to define a housing, wherein the side member is at least partially made of a metallic material, a polymer structure located in the space, and a display received in the space to be viewable through the front plat. The rear plate may be seated on the second surface.

Provided are a display control method and related products. The method includes: obtaining a target operating frequency of a modem in response to detecting that a target game initiates a game booster mode; obtaining a first MIPI operating frequency of a display MIPI bus; obtaining a target game frame rate of the target game in response to detecting the target operating frequency is interfered based on the first MIPI operating frequency; determining a target MIPI operating frequency range list corresponding to the target game frame rate; determining a second MIPI operating frequency having least interference on the target operating frequency of the modem from the plurality of MIPI operating frequencies in the target MIPI operating frequency range list; and adjusting a MIPI operating frequency of the display MIPI bus to the second MIPI operating frequency.

According to certain embodiments, an electronic device comprises: a housing; an electronic component disposed in the housing, wherein the electronic component generates heat during operation; a support cover disposed on the electronic component; a metal member overlapping with the electronic component while interposing the support cover between the metal member and the electronic component; a switching unit selectively forming or disconnecting an electrical connection path of the support cover and the metal member; and at least one processor configured to select an antenna tuning code, based at least in part on whether the switching unit forms or disconnects the electrical connection path, wherein the switching unit includes: a receiving member electrically connected to the support cover and providing a receiving space; a thermally deforming member received in the receiving space, wherein the thermally deforming member deforms based on a temperature; and an elevating member configured to move upwardly to electrically connect the metal member to the support cover, when the thermally deforming member deforms.