A compact work machine, such as a compact track loader and/or a compact utility loader, which can carry and operate a wide range of attachments while maintaining a reduced operating footprint

A compact work machine, such as a compact track loader and/or a compact utility loader, which can carry and operate a wide range of attachments while maintaining a reduced operating footprint

A compact work machine, such as a compact track loader and/or a compact utility loader, which can carry and operate a wide range of attachments while maintaining a reduced operating footprint

A compact work machine, such as a compact track loader and/or a compact utility loader, which can carry and operate a wide range of attachments while maintaining a reduced operating footprint

A compact work machine, such as a compact track loader and/or a compact utility loader, which can carry and operate a wide range of attachments while maintaining a reduced operating footprint

A compact work machine, such as a compact track loader and/or a compact utility loader, which can carry and operate a wide range of attachments while maintaining a reduced operating footprint

A compact work machine, such as a compact track loader and/or a compact utility loader, which can carry and operate a wide range of attachments while maintaining a reduced operating footprint

Discussed is a liquid crystal display device that can include a backlight unit, a switching unit disposed on an upper side of the backlight unit and including a first twisted nematic (TN) switching cell configured to change light transmittance for a first direction between a first mode and a second mode and a second twisted nematic (TN) switching cell disposed on an upper side of the first TN switching cell, and an image display layer disposed on an upper side of the switching unit. According to embodiments of the present disclosure, by providing a liquid crystal display device having a triple cell structure including two TN switching cells and one image cell, a light output for a first direction can be effectively blocked in a second mode in which partial viewing angle blocking is needed.

A set of training images are input into a neural network that outputs a pixel-wise phase matrix identifying pixels in the training images. Based on the pixel-wise phase matrix, a spatial light modulator (SLM) is actuated to output, onto a vehicle windshield, an augmented reality (AR) image including a plurality of sub-images each output in one of a plurality of focal planes. Each training image corresponds to one respective sub-image. A feedback image of the AR image is obtained via an image sensor. An offset is determined based on comparing the training images to the feedback image. Parameters of a loss function are updated based on the offset, and the updated parameters are provided to the neural network to obtain an updated offset.

Methods, systems, and apparatuses are provided for determining a position of a symbol display in an at least partially transparent operating unit for a steering wheel of a motor vehicle. A position of a symbol display unit is determined. A target position is determined for a visualization of a symbol using the symbol display relative to the symbol display unit. An average eye point when using the steering wheel relative to the symbol display unit is determined. A distance and a viewing angle of the average eye point relative to the symbol display unit is determined. A position of the symbol display in the symbol display unit is determined such that the visualization of the symbol by means of the symbol display, when viewed from the determined distance and the determined viewing angle from the average eye point, takes place at the target position for the visualization of the symbol.