lcd module vex made in china

VEX Robotics is educational robotics for everyone. VEX solutions span all levels of both formal and informal education with accessible, scalable, and affordable solutions. Beyond science and engineering principles, VEX encourages creativity, teamwork, leadership, and problem solving among groups. It allows educators of all types to engage and inspire the STEM problem solvers of tomorrow!

The V5 Robot Brain allows for "on the fly" device connection and port swapping. Legacy VEX EDR Sensors and Motors are also supported through eight 3-Wire ports.

With its Monochrome LCD screen, the V5 Controller provides users with instant feedback from the Robot Brain. Programmers can send data and multilingual text to the screen for debugging and driver information.

Yes. VEX EXP brings everything great about the V5 system to the classroom. The competition environment requires more powerful motors, additional ports, a touch screen for operation away from a computer, and longer metal structural parts for larger robots. Competition robots are weight critical and therefore use lighter, and more expensive, aluminum structures.

VEX EXP has fewer ports and lower-power motors that are more aligned with classroom needs. Since classroom use always has a computer nearby, the computer"s screen along with VEXcode can replace the function of the more expensive screens on the Brain and Controller. Lastly, only large competitions need the expensive VEXnet radio function, allowing EXP to use a more cost-effective Bluetooth solution that is robust for classroom use.

Yes. VEX EXP will support completely new STEM Labs. Some of the STEM Labs use the game field and game objects that are part of the VEX EXP Classroom Bundle. The curriculum development team will provide guidance for using all existing STEM Labs with both EXP and V5.

VEX EXP contains a large selection of parts, so there are nearly unlimited robot designs that you can build. VEX provides instructions for a beginner Basebot and Clawbot.

Yes. In fact, the VEX EXP STEM Labs are designed to bring the excitement and engagement of robotics competitions to the classroom. VEX EXP Bundles contain game fields and game objects for this reason.

We recommend EXP for the majority of the Classroom Kits so that more students can get hands-on experience with STEM and robotics. Use one V5 Competition Kit to support each of your team robots. Since all the construction parts and devices are compatible, they will seamlessly coexist in classrooms. The aluminum structural parts used for competition robots are easily differentiated from the steel structural parts in the EXP kits. Any part in the VEX EXP kits is legal for the VRC except for the EXP Robot Brain, EXP Robot Battery, and EXP Controller.

The Pin Tool makes it easy to disassemble pieces in the VEX IQ construction system. The Pin Tool has several features that can be used to make disassembling easy: the Puller, the Pusher,

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is also a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

The VEX IQ Parts Ruler is a helpful tool to help identify pieces. This ruler has a 1:1 scale, so parts can be placed directly on the printed version for easy identification. Learn More

Commercial Global Positioning System (GPS) uses satellite signals and satellite locations to triangulate a position, but not heading. The newly designed VEX GPS uses a patent-pending VEX Field Code to triangulate both position and heading.

The Field Code is mounted around the inside perimeter of the VEX field. That checkerboard pattern in the Field Code isused to identify the location for each individual block in that pattern. Like satellites, this creates hundreds of knownlocations. To sense the Field Code, the VEX GPS sensor, a black and white camera, is mounted on the rear of the robotand facing rearwards. The camera only needs to see about 17” of the code strip to triangulate a position and direction.VEX GPS is an absolute position system, so it does not drift nor does it require calibration on a per-field basis.

The most common use of Artificial Intelligence is object recognition. Humans take object recognition for granted, but robots need some help. The main reason that most robot competitions use human drivers is the robot’s lack of knowledge of its surroundings. VEX AI uses software and neural networks that can detect the game pieces, goals, and objects that VEX robots want to interact with.

Many object classification systems are designed to determine the one subject of the image with some certainty, such as a cat with 96% certainty. The VEX AI system is designed to identify hundreds of instances of various objects within an image and locate their screen coordinate. In addition the VEX AI system measures distance to each object using stereo vision. That information is combined, along with the position information from the VEX GPS to locate each object in 3D space.

The VEX LINK communication system uses a second VEX V5 VEXnet radio connected to each V5 Robot Brain to establish a robot-to-robot link. Alphanumeric strings can be sent between robots using a “message_link” protocol, similar to text messaging. Large blocks of data can also be sent using a “serial_link” protocol, similar to USB data.

VEX LINK is critical to allowing the robot to share the results of their AI object detection and GPS locations. This enables both robots to work with each other"s information, essentially giving them two points of view.

VEX AI, VEX GPS, and VEX LINK, and the resulting Sensor Fusion create an opportunity for students to take their autonomous robots a level up! The VEX AI Competition pushes the boundaries of robotics competitions. The game is separate from the VRC and VEX U competitions.

Each team brings two robots that they design and build to work as a team. Teams can 3D print and machine parts. Teams can use custom electronics, and there are no motor quantity limits. This game will be open to High School students and College students alike. Game registration will include the hardware needed for that year’s competition to run VEX AI, VEX GPS, VEX LINK, and Sensor Fusion Map.

The VEX AI Competition Pilot Program will open for registration for university level students in Fall 2020. Stay tuned for more registration updates and reminders for university level.

Click here to login to RobotEvents.com and access the VEX AI Competition High School Application. If you have any questions, please email VAIC@roboticseducation.org.

Need a new sensor that isn"t available from VEX. You have choices! Buy one and integrate it, or, even better, build it.Students can design their own circuits to enhance the capabilities of their robot. There are new skills to learn, including schematics, circuit design, microcontrollers, and new sensor technology. The possibilities are real, and the learning potential is too!

Many VEX V5 products contain their own internal processors and run on a special Operating System known as "VEXos". This Operating System is written entirely by VEX Robotics, and harnesses the flexibility and power of VEX hardware for the diverse needs of education and the rigors of competition.

VEXos allows for advanced programming features and an enhanced user experience. The best way to ensure that your V5 system is functioning properly is to keep the firmware up to date. This is done simply by opening VEXcode, then plugging your V5 Robot Brain into your computer and following the prompts. The Brain will then automatically push out the latest updates to any V5 device that is connected to it.

Greenville, TX – April 20, 2015 – Over the weekend, more than 850 teams from 29 nations gathered at the Kentucky Exposition Center to compete with custom-built robots during three days of intense back-to-back matches. Teams sought to be crowned champions of VEX Worlds 2015, the culminating event of the season, presented by the Robotics Education & Competition (REC) Foundation and the Northrop Grumman Foundation. Teams from China, New Zealand, Singapore, and the United States prevailed, taking home the highly coveted Championship Trophies for the VEX IQ Elementary & Middle School World Championships, the VEX Robotics Competition Middle & High School World Championships, and the VEX U World Championship.

Altogether, the best 850 VEX teams out of more than 12,000 teams worldwide qualified to compete in one of five program divisions hosted by the REC Foundation this past weekend. The competitions included: VEX IQ Challenge Elementary School World Championship (ages 8-10), VEX IQ Challenge Middle School World Championship (ages 11-14), VEX Robotics Competition Middle School World Championship (ages 11-14), VEX Robotics Competition High School World Championship (ages 15-18) and VEX U (ages 18+).

The VEX IQ Challenge Elementary SchoolTeamwork Challenge Winning Alliance included team 15A, Crescent Crazy Stackers, from Crescent Elementary School in Anaheim, Calif. and team 10656, Hongkou Central Primary School, from Shanghai, China.

The VEX IQ Challenge Middle School Teamwork Challenge Winning Alliance included team 2587X, DiscoBots – Xray, from Houston, Texas and team 7065A, Elementrix, from Yabucoa, Puerto Rico.

The VEX Robotics Competition Middle SchoolWorld Championship Winning Alliance included team 8193A, Shanghai Yongchang Private School, from China, and teams 8066A and 8066C, Atom and Thor, from Hai Sing Catholic School in Singapore.

The VEX Robotics Competition High SchoolWorld Championship Winning Alliance included team 2915A, Lynnfield College Robotics, from Auckland, New Zealand, team 9090C, T-VEX, from the Mandarin Chinese School, from Arlington, Texas, and team 2131C, Davis High School, from Kaysville, Utah.

One team from each of the five program divisions also received the Excellence Award, the highest honor at VEX Worlds, given to the team with the most well rounded VEX Robotics program. Team 15B, Crescent Crazy Stackers, from Crescent Elementary School in Anaheim, Calif. received the Excellence Award for the VEX IQ Challenge Elementary School Division. Team 8899Y, VEXexecutives, from Manatee County Robotics Club in Bradenton, Fla. received the Excellence Award for the VEX IQ Challenge Middle School Division. Team 7700B, Rolling Robots, from Rolling Hills Estates, Calif. was presented with the Excellent Award for the VEX Robotics Competition Middle School Division. Team 2918A, GCECA, from Glenfield College in Auckland, New Zealand received the Excellence Award for the VEX Robotics Competition High School Division. Team AURA, from Auckland University Robotics, in Auckland, New Zealand received the Excellence Award for VEX U Division.

For those looking forward to getting a jump on next year’s robot designs, the 2015-2016 season games will be VEX Bank Shot (VEX IQ Challenge) and VEX Nothing But Net (VEX Robotics Competition).

Sponsors of the 2015 VEX Robotics World Championship included the Northrop Grumman Foundation, the U.S. Army, Chevron, EMC Corporation, NASA, Microchip, Robotmatter, Texas Instruments, HEXBUG and Innovation First International. In addition, the event is sponsored locally by Ford Motor Corporation, GE, Glowtouch, HelmsBriscoe, Mathworks, Nissan, Toyota Manufacturing of Kentucky, UPS, and the University of Louisville.

LCD manufacturers are mainly located in China, Taiwan, Korea, Japan. Almost all the lcd or TFT manufacturers have built or moved their lcd plants to China on the past decades. Top TFT lcd and oled display manufactuers including BOE, COST, Tianma, IVO from China mainland, and Innolux, AUO from Tianwan, but they have established factories in China mainland as well, and other small-middium sizes lcd manufacturers in China.

China flat display revenue has reached to Sixty billion US Dollars from 2020. there are 35 tft lcd lines (higher than 6 generation lines) in China,China is the best place for seeking the lcd manufacturers.

The first half of 2021, BOE revenue has been reached to twenty billion US dollars, increased more than 90% than thesame time of 2020, the main revenue is from TFT LCD, AMoled. BOE flexible amoled screens" output have been reach to 25KK pcs at the first half of 2021.the new display group Micro LED revenue has been increased to 0.25% of the total revenue as well.

Established in 1993 BOE Technology Group Co. Ltd. is the top1 tft lcd manufacturers in China, headquarter in Beijing, China, BOE has 4 lines of G6 AMOLED production lines that can make flexible OLED, BOE is the authorized screen supplier of Apple, Huawei, Xiaomi, etc,the first G10.5 TFT line is made in BOE.BOE main products is in large sizes of tft lcd panel,the maximum lcd sizes what BOE made is up to 110 inch tft panel, 8k resolution. BOE is the bigger supplier for flexible AM OLED in China.

Technology Co., Ltd), established in 2009. CSOT is the company from TCL, CSOT has eight tft LCD panel plants, four tft lcd modules plants in Shenzhen, Wuhan, Huizhou, Suzhou, Guangzhou and in India. CSOTproviding panels and modules for TV and mobile

three decades.Tianma is the leader of small to medium size displays in technologyin China. Tianma have the tft panel factories in Shenzhen, Shanhai, Chendu, Xiamen city, Tianma"s Shenzhen factory could make the monochrome lcd panel and LCD module, TFT LCD module, TFT touch screen module. Tianma is top 1 manufactures in Automotive display screen and LTPS TFT panel.

Tianma and BOE are the top grade lcd manufacturers in China, because they are big lcd manufacturers, their minimum order quantity would be reached 30k pcs MOQ for small sizes lcd panel. price is also top grade, it might be more expensive 50%~80% than the market price.

Besides the lcd manufacturers from China mainland,inGreater China region,there are other lcd manufacturers in Taiwan,even they started from Taiwan, they all have built the lcd plants in China mainland as well,let"s see the lcd manufacturers in Taiwan:

Innolux"s 14 plants in Taiwan possess a complete range of 3.5G, 4G, 4.5G, 5G, 6G, 7.5G, and 8.5G-8.6G production line in Taiwan and China mainland, offering a full range of large/medium/small LCD panels and touch-control screens.including 4K2K ultra-high resolution, 3D naked eye, IGZO, LTPS, AMOLED, OLED, and touch-control solutions,full range of TFT LCD panel modules and touch panels, including TV panels, desktop monitors, notebook computer panels, small and medium-sized panels, and medical and automotive panels.

AUO is the tft lcd panel manufacturers in Taiwan,AUO has the lcd factories in Tianma and China mainland,AUOOffer the full range of display products with industry-leading display technology,such as 8K4K resolution TFT lcd panel, wide color gamut, high dynamic range, mini LED backlight, ultra high refresh rate, ultra high brightness and low power consumption. AUO is also actively developing curved, super slim, bezel-less, extreme narrow bezel and free-form technologies that boast aesthetic beauty in terms of design.Micro LED, flexible and foldable AMOLED, and fingerprint sensing technologies were also developed for people to enjoy a new smart living experience.

Hannstar was found in 1998 in Taiwan, Hannstar display hasG5.3 TFT-LCD factory in Tainan and the Nanjing LCM/Touch factories, providing various products and focus on the vertical integration of industrial resources, creating new products for future applications and business models.

driver, backlight etc ,then make it to tft lcd module. so its price is also more expensive than many other lcd module manufacturers in China mainland.

Maclight products included monochrome lcd, TFT lcd module and OLED display, touch screen module, Maclight is special in custom lcd display, Sunlight readable tft lcd module, tft lcd with capacitive touch screen. Maclight is the leader of round lcd display. Maclight is also the long term supplier for many lcd companies in USA and Europe.

If you want tobuy lcd moduleorbuy tft screenfrom China with good quality and competitive price, Maclight would be a best choice for your glowing business.

In this example, you will learn how to verify the output of Integrated Encoder Module block and create a model that reads the output of the encoder and use this value to control the motion of a 4-wheeled robot. The 4 wheels are powered by 2 DC motors which are connected to a VEX Microcontroller. The Simulink model will read the rotation tick count from the encoder and provide appropriate speed input to the DC motors to drive the robot to trace a square path.

In this task, you will learn how to use the Integrated Encoder Module block in a Simulink model and verify the block output using Monitor and Tune action.

4. Connect the DC motor to motor pin 3 on the VEX microcontroller. Use the Motor Controller 29 cable to establish the connection between the motor leads and the pin on VEX Microcontroller. Connect them as described on Page 4 of the VEX Microcontroller and VEXnet Joystick User Guide.

In this task, you will configure a Simulink model for parameter tuning to read the rotation of the DC Motor using the Integrated Encoder Module and display it on the Display block.

1. Open the pre-configured model(vexarmcortex_iem_externalmode). In this model, the output of the encoder block is connected to the input of a Display block. Make sure that the parameter value for Sequence order from I2C port for the encoder block is according to the sensor connection in Task 1. A Constant block provides a speed input of 30 to the DC Motor block.

In Task 1 and 2, you learned how to connect the VEX Integrated Encoder Module to the VEX microcontroller and verify the tick value read by the encoder block in External mode simulation.

Below is a figure of a 4-wheel robot platform with Integrated Encoder Modules installed on 2 DC motors. The DC motors are connected to the 2 wheels and attached to a VEX microcontroller.

4. Connect the motor attached to the left wheel to motor pin 3, and the motor attached to the right wheel to motor pin 6. Use the Motor Controller 29 cables to establish the connection between the motors leads and the pins on VEX Micrcontroller. Connect them as described on Page 4 of the VEX Microcontroller and VEXnet Joystick User Guide.

In this task, you will learn a way to model the logic for using the encoder output to control the speed of the two DC motors, thereby controlling the motion of the robot. The logic for controlling the motors is implemented in a MATLAB Function block. You will then build and download the model to the VEX microcontroller.

The parameter values Sequence order from I2C port for Integrated Encoder Module blocks in the model are as per the hardware connections in Task 3. The parameter Motor Channel for the Left Motor block is chosen as "3" and for the Right Motor block as "6" as per the hardware connections in Task 3.

9. Disconnect the USB cable from the VEX microcontroller and connect the VEXnet key to the VEX microcontroller. Turn ON the VEX microcontroller and Gamepad and place the robot on a surface where it will be able to complete a square path without encountering any obstacles. Once the VEXnet keys are paired, the robot begins to move and trace the specified path. Note that the number of ticks required for moving a certain distance on a straight line and for taking a specified degree of turn may vary slightly based on the surface on which the robot moves and the battery level. You may need to modify the required tick count slightly so that the robot is able to trace a square path on the desired surface.

Perform the same exercise using Optical Shaft Encoder by replacing Integrated Encoder Module blocks. You can use the preconfigured models for Verification of Optical Shaft Encoder block(vexarmcortex_shaftencoder_externalmode) and Square Path Navigating Robot using Optical Shaft Encoder(vexarmcortex_shaftencoder_navigate). Given below are the required hardware connections if you use the preconfigured models.

Plug the bottom wire of the left encoder to digital port 2 on the VEX Microcontroller. Place the encoder such that its removable side is facing up to identify the top and bottom wires of the encoder.

In this example, you will learn how to verify the output of Ultrasonic sensor block and create a model that reads the output of VEX Ultrasonic sensor and use this value to control the motion of a 4-wheeled robot. The 4 wheels are powered by 2 DC motors which are connected to a VEX Microcontroller. The Simulink model will read the distance value from the Ultrasonic sensor and provide appropriate speed input to the DC motors to drive the robot.

Below is a figure of a 4-wheel robot platform with Ultrasonic sensor connected and 2 DC motors connected to the 2 wheels and attached to a VEX microcontroller.

1. Open the pre-configured model(vexarmcortex_ultrasonic_externalmode). In this model, the output of Ultrasonic Sensor block is connected to the input of a Display block. Make sure that the parameter values for INPUT (Ping Port) and OUTPUT (Echo Port) of Ultrasonic Sensor block are chosen according to the sensor connection in Task 1.

3. While the model is running, place an object at a certain distance from the VEX Ultrasonic sensor and observe the distance value on the Display block in the Simulink model. Observe that the distance value increases when the object is moved away from the sensor and decreases when the object is moved towards the sensor.

In Task 1 and 2, you learned how to connect the VEX Ultrasonic sensor to the VEX microcontroller and verify the distance value read by the Ultrasonic Sensor block while performing Monitor and Tune action.

2. The two DC motors drive the left and right set of wheels on the robot platform. Connect the two DC motor pins on the VEX microcontroller. The motor connected to the left wheel should be connected to the motor pin 6, and the motor connected to the right wheel to pin 3. Use the Motor Controller 29 cables to establish the connection between the motors leads and the pins on VEX Microcontroller. Connect them as described on Page 4 of the VEX Microcontroller and VEXnet Joystick User Guide.

In this task, you will learn a way to model the logic for using the Ultrasonic Sensor block output to control the speed of the two DC motors, thereby controlling the motion of the robot. The logic for controlling the motor speed is implemented in a Stateflow chart. You will then build and download the model to the VEX microcontroller.

9. Disconnect the USB cable from the VEX microcontroller and connect the VEXnet key to the VEX microcontroller. Turn ON the VEX microcontroller and Gamepad. Once the VEXnet keys are paired, the robot begins to move. Place an object at some distance in front of the robot and observe that the robot stops moving once it is 0.2 m away from the object. Increase the distance between the robot and the object and observe that the robot starts moving again until the distance between them is 0.2 m or less.