Solid State Relay

A solid-state relay is an ON-OFF control device in which the load current is conducted by one or more semiconductors

e.g., a power transistor, an SCR, or a TRIAC.

Types of SSR’s

It is convenient to classify SSR’s by the nature of the input circuit, with particular reference to the means by which input-output isolation is achieved. Three major categories are recognized:

Reed-Relay-Coupled SSR’s 

When the control signal is applied (directly, or through a preamplifier) to the coil of a reed relay. The closure of the reed switch then activates appropriate circuitry that triggers the thyristor switch. Clearly, the input-output isolation achieved is that of the reed relay, which is usually excellent.

Transformer-Coupled SSR’s 

When the control signal is applied (through a DC-AC converter, if it is DC, or directly, if It is AC) to the primary of a small, low-power transformer, and the secondary voltage that results from the primary excitation is used (with or without rectification, amplification, or other modification) to trigger the thyristor switch. In this type, the degree of input-output isolation depends on the design of the transformer.

Photo-coupled SSR’s

When the control signal is applied to a light or infrared source (usually, a light-emitting diode, or LED), and the radiation from that source is detected in a photo-sensitive semiconductor (i.e., a photosensitive diode, a photo-sensitive transistor, or a photo-sensitive thyristor). The output of the photo-sensitive device is then used to trigger (gate) the TRIAC or the SCR’s that switch the load current. Clearly, the only significant “coupling path” between input and output is the beam of light or infra-red radiation, and electrical isolation is excellent. These SSR’s are also referred to as “optically coupled” or “photo isolated”.

List of Integrated Development Environments (IDEs) for Android App Development

An Integrated Development Environment (IDE) is allows an application (app) developer to perform the software development. Software development consists of to design, write (or code), compile, test, debug and package the app software.

For Android app development Google currently supports two IDEs (but read on for a list of alternative IDEs and languages):

1. Android Developer Tools (ADT) – http://developer.android.com/sdk/index.html
2. Android Studio – http://developer.android.com/sdk/installing/studio.html (in beta)
   

List of Alternative Android App Development IDEs

Name	Language	URL
AIDE (Android IDE)	HTML5/C/C++	http://www.android-ide.com/
Application Craft	HTML5	http://www.applicationcraft.com/
Basic4Android	BASIC	http://www.basic4ppc.com/
Cordova	HTML5	https://cordova.apache.org/
Corona	Lua	http://coronalabs.com/
Intel XDK	HTML5	https://software.intel.com/en-us/html5/tools
IntelliJIDEA	Java	https://www.jetbrains.com/idea/features/android.html
Kivy	Python	http://kivy.org/#home
Lazarus IDE+free pascal+LAWM	Pascal	http://www.lazarus-ide.org/, http://www.freepascal.org/, LAWM
MIT App Inventor	Blocks	http://appinventor.mit.edu/explore/
Monkey X	BASIC	http://www.monkeycoder.co.nz/
MonoGame	C#	http://www.monogame.net/
MoSync	HTML5/C/C++	http://www.mosync.com/
NS BASIC	BASIC	https://www.nsbasic.com/
PhoneGap	HTML5	http://phonegap.com/
RAD Studio XE	Object Pascal, C++	http://www.embarcadero.com/
RFO Basic	BASIC	http://laughton.com/basic/
RhoMobile Suite	Ruby	http://www.motorolasolutions.com/US-EN/Business+Product+and+Services/Software+and+Applications/RhoMobile+Suite
Telerik	HTML5	http://www.telerik.com/platform#overview
Titanium	JavaScript	http://www.appcelerator.com/titanium/titanium-sdk/
Xamarin	C#	http://xamarin.com/

Basic DC Ammeter

An ammeter is an instrument used for measuring the electric current in a branch of an electric circuit. It must be placed in series with the measured branch, and must have very low resistance to avoid significant variation of the current it is to measure. The ammeter is also used the principle of d’Arsonval meter movement with slight modification. A low value resistor (shunt resistor) is used in DC ammeter to measure large current.

Voltage across meter resistor ( Rm ) is given by,

Vm= Im Rm

Voltage across shunt resistor ( Rsh ) is given by,

Vsh= Ish Rsh

Meter resistor and shunt resistor are connected in parallel, so voltage drop across resistor is same,

ImRm= IshRsh

I = (Ish + Im)

Ish = (I –Im)

Rsh =( ImRm)/(I –Im)

Where,

Rm= internal resistance of the movement.

Rsh= shunt resistance

Ish= shunt current

Im= full scale deflection current of the movement

I = full scale current of the ammeter + shunt

 

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Metal Detector

                               

This metal detector can be used to detect metallic objects. Sensing coil is used to detect metals. This coil should be kept near metallic objects for detection. Sensing coil forms parts of tuned oscillator. Input of circuit is a weak colpitt’s R.F. range oscillator.

Working:

When coil is brought near a metallic object magnetic energy is absorbed and oscillator fails to work then transistor Q4 conducts and buzzer is activated. Use a 9 V battery. After connecting battery, adjust the 4.7K preset till circuit just stop sounding.

Block Diagram:

Circuit Diagram:

 Component Part List:

1

 1. Resistors

 2. Capacitors:

3     3. Diodes:

 4. Transistors:

       5. Miscellaneous:

ECDT Lab Manual

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