JV Electronic chennai

23/02/2021

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20/09/2019

16/09/2019

Green tech future innovation
OLED LED 4K advanced update technology training in 12-10-2019 booking start
limited seats available

Interested person use this link jointly this innovation update training

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16/09/2019

GREEN TECH future innovations training

In Chennai

*GREEN TECH FUTURE INNOVATION* *provides Electronic Service engineer future skill development training program*

*Training Highlights*

*LED*, *OLED* , *4K, 8k tv* *ANDROID board reparing methods, *Universal board installation*, *software Updates* & *easy chip level servicing method*, *new tips services panel issues* &
*pannel bypass method*, *Shortcut method for panel issues*

*Introduction to future energy solor technology*

Advance type of *solar panel installation*, *solar panel inner cell service methods*,

*Drone camera*(helipad camera) *PHANTOM 4* drone circuit design & installation and operational methods, service methods, practical

For Advertisement purpose used *LED video wall display DIY KIT* *raspberry p4 arduino* and *4k technology controller* board installation and service methods,

circuit designing for *Arduino technologies* *electric motor vehicles*, Technology training for battery vehicles,

These are all trainings given by worldclass experienced trainers in our institution.

we are conducting *practical training* for this new latest technology with low cost.

" *Technician's brightful future is our Motto* "

*Please participate in this training and improve your Livelihood*.

*We have whatsapp support after the training.*

*Green tech future innovation* *TEAM*
*Our Trainers*
*B.Jesusraja E.C.E*
*J.V.Vasanth E.E.E, B.E*
*R.Mohan B.E.S*
*(Ex.Philips, Seimens*)
*S.Ashok Raja AVS* *(Srilanka)*

*Technician's bright future is our Motto*"

*So kindly grab this oppurtunity*

Day: *12-10-2019*
Time: *9Am to 6Pm*
Place : *Jaya Pushpam
No.1131 Inner ring road,
*Koyambedu (CMBT) bus stand entrance opposite)*
*Chennai*

*Send your payment in advance to book your seat*:

*Fees : 3500 Rs*

*J.Vasanthkumar*
*City Union Bank*
*A/c no* 500101011948814
*IFSC* : CIUB0000517
*RAMAPURAM BRANCH*

*R.MOHAN*
*IDBI BANK*
*A/c no* :200210400001625
*IFSC* : IBKL0002002
*ARUMBAKKAM BRANCH*

*RAJENDRAN BALARAMAN*
*THE SOUTH INDIAN BANK*
*A/c no* 0029053000017138
*IFSC* : SIBL0000029
*KANCHEEPURAM BRANCH*

08/01/2019

29/09/2018

What is a LCD

(Liquid Crystal Display)?
A liquid crystal display or LCD draws its definition from its name itself. It is combination of two states of matter, the solid and the liquid. LCD uses a liquid crystal to produce a visible image. Liquid crystal displays are super-thin technology display screen that are generally used in laptop computer screen, TVs, cell phones and portable video games. LCD’s technologies allow displays to be much thinner when compared to cathode ray tube (CRT) technology.

Liquid crystal display is composed of several layers which include two polarized panel filters and electrodes. LCD technology is used for displaying the image in notebook or some other electronic devices like mini computers. Light is projected from a lens on a layer of liquid crystal. This combination of colored light with the grayscale image of the crystal (formed as electric current flows through the crystal) forms the colored image. This image is then displayed on the screen.
An LCD is either made up of an active matrix display grid or a passive display grid. Most of the Smartphone’s with LCD display technology uses active matrix display, but some of the older displays still make use of the passive display grid designs. Most of the electronic devices mainly depend on liquid crystal display technology for their display. The liquid has a unique advantage of having low power consumption than the LED or cathode ray tube.

Liquid crystal display screen works on the principle of blocking light rather than emitting light. LCD’s requires backlight as they do not emits light by them. We always use devices which are made up of LCD’s displays which are replacing the use of cathode ray tube. Cathode ray tube draws more power compared to LCD’s and are also heavier and bigger Simple facts that should be considered while making an LCD:


The basic structure of LCD should be controlled by changing the applied current.
We must use a polarized light.
Liquid crystal should able be to control both of the operation to transmit or can also able to change the polarized light.
As mentioned above that we need to take two polarized glass pieces filter in the making of the liquid crystal. The glass which does not have a polarized film on the surface of it must be rubbed with a special polymer which will create microscopic grooves on the surface of the polarized glass filter. The grooves must be in the same direction of the polarized film. Now we have to add a coating of pneumatic liquid phase crystal on one of the polarized filter of the polarized glass. The microscopic channel cause the first layer molecule to align with filter orientation. When the right angle appears at the first layer piece, we should add a second piece of glass with the polarized film. The first filter will be naturally polarized as the light strikes it at the starting stage.

Thus the light travels through each layer and guided on the next with the help of molecule. The molecule tends to change its plane of vibration of the light in order to match their angle. When the light reaches to the far end of the liquid crystal substance, it vibrates at the same angle as that of the final layer of the molecule vibrates. The light is allowed to enter into the device only if the second layer of the polarized glass matches with the final layer of the molecule.

How LCDs Work?
The principle behind the LCD’s is that when an electrical current is applied to the liquid crystal molecule, the molecule tends to untwist. This causes the angle of light which is passing through the molecule of the polarized glass and also cause a change in the angle of the top polarizing filter. As a result a little light is allowed to pass the polarized glass through a particular area of the LCD. Thus that particular area will become dark compared to other. The LCD works on the principle of blocking light. While constructing the LCD’s, a reflected mirror is arranged at the back. An electrode plane is made of indium-tin oxide which is kept on top and a polarized glass with a polarizing film is also added on the bottom of the device. The complete region of the LCD has to be enclosed by a common electrode and above it should be the liquid crystal matter.

Next comes to the second piece of glass with an electrode in the form of the rectangle on the bottom and, on top, another polarizing film. It must be considered that both the pieces are kept at right angles. When there is no current, the light passes through the front of the LCD it will be reflected by the mirror and bounced back. As the electrode is connected to a battery the current from it will cause the liquid crystals between the common-plane electrode and the electrode shaped like a rectangle to untwist. Thus the light is blocked from passing through. That particular rectangular area appears blank.

Advantages of an LCD’s:

LCD’s consumes less amount of power compared to CRT and LED
LCD’s are consist of some microwatts for display in comparison to some mill watts for LED’s
LCDs are of low cost
Provides excellent contrast
LCD’s are thinner and lighter when compared to cathode ray tube and LED
Disadvantages of an LCD’s:

Require additional light sources
Range of temperature is limited for operation
Low reliability
Speed is very low
LCD’s need an AC drive
Applications of Liquid Crystal Display

Liquid crystal technology has major applications in the field of science and engineering as well on electronic devices.

Liquid crystal thermometer
Optical imaging
The liquid crystal display technique is also applicable in visualization of the radio frequency waves in the waveguide
Used in the medical applications

05/09/2018

MOSFET with Working? MOSFET as a Switch
Introduction:
The MOSFET (Metal Oxide Semiconductor Field Effect Transistor) transistor is a semiconductor device which is widely used for switching and amplifying electronic signals in the electronic devices. The MOSFET is a core of integrated circuit and it can be designed and fabricated in a single chip because of these very small sizes. The MOSFET is a four terminal device with source(S), gate (G), drain (D) and body (B) terminals. The body of the MOSFET is frequently connected to the source terminal so making it a three terminal device like field effect transistor. The MOSFET is very far the most common transistor and can be used in both analog and digital circuits.
The MOSFET works by electronically varying the width of a channel along which charge carriers flow (electrons or holes). The charge carriers enter the channel at source and exit via the drain. The width of the channel is controlled by the voltage on an electrode is called gate which is located between source and drain. It is insulated from the channel near an extremely thin layer of metal oxide. The MOS capacity present in the device is the main part
The MOSFET can function in two way

When there is no voltage on the gate, the channel shows its maximum conductance. As the voltage on the gate is either positive or negative, the channel conductivity decreases. Working Principle of MOSFET:
The aim of the MOSFET is to be able to control the voltage and current flow between the source and drain. It works almost as a switch. The working of MOSFET depends upon the MOS capacitor. The MOS capacitor is the main part of MOSFET. The semiconductor surface at the below oxide layer which is located between source and drain terminal. It can be inverted from p-type to n-type by applying a positive or negative gate voltages respectively. When we apply the positive gate voltage the holes present under the oxide layer with a repulsive force and holes are pushed downward with the substrate. The depletion region populated by the bound negative charges which are associated with the acceptor atoms. The electrons reach channel is formed. The positive voltage also attracts electrons from the n+ source and drain regions into the channel. Now, if a voltage is applied between the drain and source, the current flows freely between the source and drain and the gate voltage controls the electrons in the channel. Instead of positive voltage if we apply negative voltage , a hole channel will be formed under the oxide layer.
P-Channel MOSFET:
The P- Channel MOSFET has a P- Channel region between source and drain. It is a four terminal device such as gate, drain, source, body. The drain and source are heavily doped p+ region and the body or substrate is n-type. The flow of current is positively charged holes. When we apply the negative gate voltage, the electrons present under the oxide layer with are pushed downward into the substrate with a repulsive force. The depletion region populated by the bound positive charges which are associated with the donor atoms. The negative gate voltage also attracts holes from p+ source and drain region into the channel region.
N- Channel MOSFET:
The N-Channel MOSFET has a N- channel region between source and drain It is a four terminal device such as gate, drain , source , body. This type of MOSFET the drain and source are heavily doped n+ region and the substrate or body is P- type. The current flows due to the negatively charged electrons. When we apply the positive gate voltage the holes present under the oxide layer pushed downward into the substrate with a repulsive force. The depletion region is populated by the bound negative charges which are associated with the acceptor atoms. The electrons reach channel is formed. The positive voltage also attracts electrons from the n+ source and drain regions into the channel. Now, if a voltage is applied between the drain and source the current flows freely between the source and drain and the gate voltage controls the electrons in the channel. Instead of positive voltage if we apply negative voltage a hole channel will be formed under the oxide layer. In this circuit arrangement an enhanced mode and N-channel MOSFET is being used to switch a sample lamp ON and OFF. The positive gate voltage is applied to the base of the transistor and the lamp is ON (VGS =+v) or at zero voltage level the device turns off (VGS=0). If the resistive load of the lamp was to be replaced by an inductive load and connected to the relay or diode which is protect to the load. In the above circuit, it is a very simple circuit for switching a resistive load such as lamp or LED. But when using MOSFET to switch either inductive load or capacitive load protection is required to contain the MOSFET device. We are not giving the protection the MOSFET device is damage. For the MOSFET to operate as an analog switching device, it needs to be switched between its cutoff region where VGS =0 and saturation region where VGS =+v.
MOSFET is also a transistor. We abbreviate it as Metal Oxide Silicon Field Effect Transistor. It will have P-channel and N-channel. It consists of a source, gate and drain. Here we connected a resistive load of 24Ω in series with an ammeter, and a voltage meter connected across the MOSFET. In the transistor the current flow in the gate is in positive direction and source goes to ground. In BJT’s, the current flow is base-to-emitter circuit. But in MOSFET there is no current flow because there is a capacitor at the beginning of the gate, it just requires only voltage. We will know this by doing the simulation process with switching ON/OFF. When the switch is ON there is no current flow in the circuit, when we taken a resistance of 24Ω and 0.29 of ammeter voltage then we find negligible voltage drop across the source because there is +0.21V across MOSFET.

Resistance between drain and source is called RDS. Because of RDS, the voltage drop appears while current flow in circuit. RDS varies depending on the type of MOSFET (it could be 0.001, 0.005, and 0.05 depending on the voltage type).

Finally, we will conclude that, the transistor requires current whereas MOSFET require voltage. The driving requirement for the MOSFET is much better, much simpler as compared to a BJT.

05/09/2018

LCD: liquid crystal display. Works by adjusting the amount of light blocked. Usually has a backlight but might not (clocks, calculators, Nintendo Gameboy). The green-black ones can be very cheap and are a mature technology. Response time can be slow.

TFT: is a type of LCD with a thin film transistor attached to each pixel. All computer LCD screens are TFT since early 2000s; older ones had slower response times and poorer colour. Cost is now very good; power consumption is fairly good but dominated by the backlight. Has to be manufactured out of glass.

LED: light emitting diode. As the name suggests, emits light rather than blocking it like LCD. Used for red/green/blue/white indicator lights everywhere. Some manufacturers advertise "LED" displays that are TFT screens with a white LED backlight, which is just confusing. Ones that are real LED screens are usually OLED.

OLED: organic LED (rather than silicon or germanium based like regular LEDs). Comparatively recent technology, so cost still quite variable and not available in really large sizes. In theory can be printed on plastic, resulting in lighter flexible displays with good brightness, good power consumption and good response time.

Best power consumption of all of these is a monochrome infrequently changing LCD display with no backlight.

18/07/2018

Today Available this lot of led LIGHTS and and plants high power led lights PHILIPS brand only for JV ELECTRONICS