LCD liquid crystal display interface

LCD liquid crystal display Interface

The RGB color mode is a color standard in the industry. It obtains various colors by changing the three color channels of red (R), green (G), and blue (B) and superimposing them with each other. Yes, RGB is the color representing the three channels of red, green, and blue. This standard includes almost all the colors that human vision can perceive, and it is one of the most widely used color systems.

LVDS

The reason why LVDS has become the preferred signal form of high-speed I/O interface to solve the limitation of high-speed data transmission is because it has advantages in transmission speed, power consumption, anti-noise, EMI, etc.

① High-speed transmission capability. In the LVDS standard defined by ANS/EIA/EIA-64, the theoretical limit rate is 1.923Gbps. The working mode of constant current source mode and low swing output determines the high-speed driving capability of IVDS.

②Low power consumption characteristics. LVDS devices are implemented using CMOS technology, and CMOS can provide lower static power consumption; when the drive current of the constant current source is 3.5mA, the power consumption of the load (100Ω terminal matching) is only 1.225mW; the power consumption of LVDS is Constant, unlike the dynamic power consumption of CMOS transceivers that rise with respect to frequency. The drive design of the constant current source mode reduces the system power consumption and greatly reduces the influence of frequency components on power consumption. Although the power consumption of CMOS is lower than that of LVDS when the speed is low, as the frequency increases, the power consumption of CMOS will gradually increase, and eventually it will consume more power than LVDS. Generally, when the frequency is equal to 200MSps, the power consumption of LVDS and CMOS is roughly the same.

③The power supply voltage is low. With the development of integrated circuits and the requirement for higher data rates, low-voltage power supply has become an urgent need. Lowering the power supply voltage not only reduces the power consumption of high-density integrated circuits, but also reduces the heat dissipation pressure inside the chip, which helps to improve integration. LVDS drivers and receivers do not depend on specific power supply voltage characteristics, which determines that it occupies the top in this regard.

④Strong anti-noise ability. The inherent advantage of the differential signal is that noise is coupled to a pair of differential lines in a common mode, and subtracted in the receiver, thereby eliminating noise, so LVDS has a strong ability to resist common mode noise.

⑤ Effectively suppress electromagnetic interference. Because the polarities of the differential signals are opposite, the electromagnetic fields radiated by them can cancel each other out. The tighter the coupling, the less electromagnetic energy leaked to the outside, which reduces EMI.

⑥ Precise timing positioning. Because the switch change of the differential signal is at the intersection of the two signals. Unlike ordinary single-ended signals, which rely on high and low threshold voltages to judge, it is less affected by process and temperature, which can reduce errors in timing and facilitate the effective transmission of high-speed digital signals.

⑦ Adapt to a large range of ground plane voltage changes. The LVDS receiver can withstand at least ±1V of the ground voltage change between the driver and the receiver. Since the typical bias voltage of the IVDS driver is +1.2V, the sum of the ground voltage change, the driver's bias voltage, and the lightly coupled noise, is a common-mode voltage at the receiver input relative to the driver's ground. When the swing does not exceed 400mV, the common-mode range is +0.2V+2.2V, and in general, the input voltage range of the receiver can vary within 0V+2.4V.