The present invention provides an image pickup device that recognizes the object that the user is attempting to capture as the subject, tracks the movement of that subject, and can continue tracking the movement of the subject even when the subject leaves the capturing area so that the subject can always be reliably brought into focus. The image pickup device includes a main camera that captures the subject; an EVF that displays the captured image captured by the main camera, a sub-camera that captures the subject using a wider capturing region than the main camera, and a processing unit that extracts the subject from the captured images captured by the main camera and the sub-camera, tracks the extracted subject, and brings the subject into focus when an image of the subject is actually captured. When the subject moves outside of a capturing region of the main camera, the processing unit tracks the subject extracted from the captured image captured by the sub-camera.

Device scaling has increased the device density of integrated circuits (ICs) and reduced the cost of circuits. Today development of new device structures, use of new materials and complex process steps are implemented to continue scaling of the semiconductor devices. The added manufacturing steps and complexity have increased cost of ICs directly impacting the implementation of IoT devices that need low cost and high yields to be successful. ALEFT-M-LTSEE is a device that reduces cost while improving device performance by S/D resistance reduction. ALEFT-M-LTSEE enable scaling of gate and channel lengths while reducing impact of random threshold variation due to discrete dopants in and around the channel. By creating a flat field profile at the gate by use of low temperature epitaxy as source/drain extension, the short channel effects, and the impact of line edge variations of the gate are reduced.

Object is to provide a semiconductor device having improved reliability or performance. A high-breakdown-voltage n type transistor has source and drain regions having first, second, and third semiconductor regions, which are formed by ion implantation of a first impurity from the outside of a high-breakdown-voltage gate electrode, a second impurity from the outside of the high-breakdown-voltage gate electrode and a first sidewall insulating film, and a third impurity from the outside of the high-breakdown-voltage gate electrode and the first and second sidewall insulating films, respectively. The first and second impurities are implanted from a direction tilted by 45 relative to the main surface of the semiconductor substrate and the third impurity from a direction perpendicular thereto. The impurity concentration of the first semiconductor region is lower than that of the second one and the ion implantation energy of the first impurity is greater than that of the second impurity.

Semiconductor devices including a stressor in a recess and methods of forming the semiconductor devices are provided. The methods may include forming a trench in an active region and the trench may include a notched portion of the active region. The methods may also include forming an embedded stressor in the trench. The embedded stressor may include a lower semiconductor layer and an upper semiconductor layer, which has a width narrower than a width of the lower semiconductor layer. A side of the upper semiconductor layer may not be aligned with a side of the lower semiconductor layer and an uppermost surface of the upper semiconductor layer may be higher than an uppermost surface of the active region.

According to an embodiment, a semiconductor device is provided. The device includes: The second region has a greater curvature than the first region. The device includes: an N-type epitaxy layer; a P-well in the N-type epitaxy layer; a drain in the N-type epitaxy layer; a source in the P-well; and a bulk in the P-well and in contact with the source, wherein the bulk has a greater area in the second region than in the first region.

A flash memory disposed on a substrate is provided. The flash memory includes a semiconductor transistor including stacked gate structures, lightly doped regions and spacers. The stacked gate structures include a gate dielectric layer, a first conductive layer, a dielectric layer and a second conductive layer sequentially disposed on the substrate. The dielectric layer has an opening there around such that the first conductive layer electrically connects with the second conductive layer. The lightly doped regions are disposed in the substrate under the opening at sides of the stacked gate structures. The spacers are disposed on sidewalls of the stacked gate structures. A width of spacers is adjusted by controlling a height of the first conductive layer under the opening. The lightly doped regions are disposed by using the dielectric layer as a mask layer, so as to gain margins of the lightly doped regions for good electrical properties.

A method for fabricating semiconductor device includes the steps of first providing a substrate having a high-voltage (HV) region and a low-voltage (LV) region, forming a first gate structure on the HV region and a second gate structure on the LV region, forming a first lightly doped drain (LDD) adjacent to one side of the first gate structure and a second LDD adjacent to another side of the first gate structure, and then forming a third lightly doped drain (LDD) adjacent to one side of the second gate structure and a fourth LDD adjacent to another side of the second gate structure. Preferably, the first LDD and the second LDD are asymmetrical, the third LDD and the fourth LDD are asymmetrical, and the second LDD and the third LDD are symmetrical.

The present invention provides an image pickup device that recognizes the object that the user is attempting to capture as the subject, tracks the movement of that subject, and can continue tracking the movement of the subject even when the subject leaves the capturing area so that the subject can always be reliably brought into focus. The image pickup device includes a main camera that captures the subject; an EVF that displays the captured image captured by the main camera, a sub-camera that captures the subject using a wider capturing region than the main camera, and a processing unit that extracts the subject from the captured images captured by the main camera and the sub-camera, tracks the extracted subject, and brings the subject into focus when an image of the subject is actually captured. When the subject moves outside of a capturing region of the main camera, the processing unit tracks the subject extracted from the captured image captured by the sub-camera.

A fabricating method of a high voltage transistor includes providing a high voltage transistor. The high voltage transistor includes a substrate. A gate structure is disposed on the substrate. A source drift region and a drain drift region are respectively disposed at two sides of the gate structure and embedded within the substrate. A source is disposed in the source drift region. A drain is disposed within the drain drift region. The steps of fabricating the drain drift region include defining a drain drift region predetermined region on the substrate by using a photo mask. The photo mask includes a first comb-liked pattern. The first comb-liked pattern includes a first rectangle and numerous first tooth structures. Then, an ion implantation process is performed to implant dopants into the drain drift region predetermined region. Then, dopants in the drain drift region predetermined region are diffused to form the drain drift region.

In some embodiments, the present disclosure relates to a semiconductor device comprising a source and drain region arranged within a substrate. A conductive gate is disposed over a doped region of the substrate. A gate dielectric layer is disposed between the source region and the drain region and separates the conductive gate from the doped region. A bottommost surface of the gate dielectric layer is below a topmost surface of the substrate. First and second sidewall spacers are arranged along first and second sides of the conductive gate, respectively. An inner portion of the first sidewall spacer and an inner portion of the second sidewall spacer respectively cover a first and second top surface of the gate dielectric layer. A drain extension region and a source extension region respectively separate the drain region and the source region from the gate dielectric layer.