Friday, October 31, 2014

1000W MOSFET LEGEND stage Master MK2

We have 1000Watt MOSFET LEGEND stage Master MK2 is a very good and powerful amplifier. It is not into the classroom HiEnd sure, but very respectable sounding unit with lots of of power. It was not designed with home interior as the primary goal before, such a power used only rarely in the house and indoor except perhaps in some larger nightclubs. Frankly, due to a high performance, could PA light rather go class, but other specifications and great quality over the PA standards and needs! My only additional suggestion for you to think about it at length, Master internship as a Master MK2. Internship Master 500… 1000W, but is a a little easier (and cheaper) to build. ” PCB show thus as below 1000W mosfet PCB 1000W mosfet PCB
                                                                 Scematic Diagram
 
                                                                  Layout PCB
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OCL Power Amplifier Circuit MJ15003 MJ15004

This Power Amp OCL 100 watt circuit by transistors.They has been an old circuits, but very well amplifier schematic. We use only all transistor MJ15003 and MJ15004 is the main in circuits, and the power supply +38V 0 -38V 3A. follow stye of OCL amp and They has Specification are
power output : 105watt at 4 ohm load, 88watt at 8 ohms load
input sensitivity : 0.5V
Frequency response : 10-10kHZ +/- 1dB
THD: 0.07% at 50 watt , 0.1% at 100 watt.

This power amp OCL 100w is a very excellent sound quality. Since we provide the circuit in look All direct coupling form is connection join together direct all, to cut-off frequency low-loss problems, the super bass really do not tell who.
The signal Input of the tone controls enter via C1 to the base pin of transistor Q1, which together with the Q2 is differential amplifier, the signal from the collection pin of Q1 supplied to the bas pin of the Q5, which it acts as the pre-driver circuit.
- The transistor Q4 is setting level bias or act as to control Idle current in this circuit. Which we can adjust level idle current by By adjusting the VR1.
- The transistor Q3 acts as a boost trapping.
- The output signal from the Q5 will enter to base pin of Q8,Q9.which acts as the driver circuit. For the signal output to drive the output transistors Q10, Q11.
- Both output transistors Q10, Q11, we used the number on the circuit are MJ15003, MJ15004. This couple can use up to 200W, so not problem in durability.
If you want to save. May be represented by a pair of output are 2N3055, MJ2955 each of the two parallel each other instead.

OCL
100W OCL Power Amplifier Circuit MJ15003,MJ15004

Creation
-Check the assembly of all equipment to correct the circuit, without the output transistors, Using a voltmeter measure the voltage at the speaker. By also does not have a speaker. At the end of this process was completed and ready to operate immediately.
-Put the power supply to the circuit, then to measure the voltage is 0V or not higher than 0.25V, if not in this means that the circuit failure, need to check first.
-The later, on output transistors, and then use an ammeter to measure the current is supplied with short input circuit. Measuring that positive or negative wire. Then, adjust VR1 until reading about the current 20-40 mA.
- For transistor Q4, when the device successfully. Should be installed on the cooling pad. Which installation of the output transistor. To help control the the bias current output relative to the temperature change of the output transistor.
- The power supply circuit is got by power of transformer T1, which provides voltage to the coil in the secondary coil is 27-0-27 volt, 5 amp.
- The Diodes Bridge rectifier should be not lower than 5 Amp 100V, The filter capacitor C7, C8 we used a 1,000uF 50V, the voltage at the capacitor afer through the filter will can about 38V.
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Master Slave Switch Circuit

In this age of enlightenment any sort of relationship that could be described as master/slave would be questionable but for the purposes of this circuit it gives a good idea of how it functions. The circuit senses mains current supplied to a ‘master’ device and switches ‘slave’ equipment on or off. This feature is useful in a typical hi-fi or home computer environment where several peripheral devices can all be switched on or off together. A solid-state relay from Sharp is an ideal switching element in this application; a built-in zero crossing detector ensures that switching only occurs when the mains voltage passes through zero and any resultant interference is kept to an absolute minimum.

master-slave-switch-circuit-diagramw

Master/Slave Switch Circuit Diagram

All of the triac drive circuitry (including optical coupling) is integrated on-chip so there are very few external components and no additional power supply necessary. This makes the finished design very compact. Diodes D1, D2, D3 and D4 perform the current sensing function and produce a voltage on C2 when the master equipment is switched on. A Schottky diode is used for D5 to reduce forward voltage losses to a minimum. The circuit is quite sensitive and will successfully switch the slave even when the master equipment draws very little mains current. The RC network formed by R1 and C1 provides some protection for the solid-state relay against mains-borne voltage transients.

Warning:

This circuit is connected to the mains. it is important to be aware that the chip has lethal voltages on its pins and all appropriate safety guidelines must be adhered to! This includes the LED, for safety it must be fitted behind a transparent plexiglass shield.

Author: Karl Köckeis - Copyright: Elektor July-August 200

Source : www.extremecircuits.net

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Thursday, October 30, 2014

Circuit 150W amplifier with active crossover

stereo
Series 150W Amplifier With Active Crossover Series 150W Amplifier with Active Crossover is very interesting. Actually, this circuit uses 4-channel power amplifier chip. Well, as an Active Crossover here we use also a chip that can separate the tone of the bass, midrange and treble, the output from the Active Crossover can be directly amplified by power amplifier.

Power Chip 4-channel amplifier that we use is SANYO LA47536 who have power outputs up to 150W, while for Active Crossover (Active Crossover) we use the LF353 from National Semiconductor.

stereo
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UM3561 Heat detector alarm circuit with explanation

 um3561 heat detector alarm circuit with explanation
A very simple heat detector alarm electronic project can be designed using the UM3561 sound generator circuit and some other common electronic parts . This heat detector electronic circuit project uses a complementary pair comprising npn and pnp transistor to detect heat . Collector of T1 transistor is connected to the base of the T2 transistor , while the collector of T2 transistor is connected to RL1 relay . T3 and T4 transistors connected in darlington configuration are used to amplify the audio signal from the UM3561 ic .
When the temperature close to the T1 transistor is hot , the resistance to the emitter –collector goes low and it starts conducting . In same time T2 transistor conducts , because its base is connected to the collector of T1 transistor and the RL1 relay energized and switches on the siren which produce a fire engine alarm sound .
This electronic circuit project must be powered from a 6 volts DC power supply , but the UM3561 IC is powered using a 3 volt zener diode , because the alarm sound require a 3 volts dc power supply .
The relay used in this project must be a 6 volt / 100 ohms relay and the speaker must have a 8 ohms load and 1 watt power
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Equalising HEXFETs diagram

When experimenting with audio output stages featuring multiple HEXFETs it quickly becomes apparent that the total power is not divided equally among the individual transistors. The reason for this lies in the wide part-to-part variations in gate-source voltage, which in the case of the IRFP240 (or IRFP9240) can be from 2 V to 4 V. Source resistors in the region of 0.22 Ω as commonly seen in amplifier circuits (see example circuit extract) help to counteract this, but usually not to a sufficient extent. One possible solution to this problem is to ‘select’ the transistors used so that their gate-source voltages match as closely as possible.


For building prototypes or very short production runs this is feasible, but requires additional manual effort in testing the components, and, of course, more transistors must be ordered than will finally be used. The circuit idea shown here allows differences in gate-source voltage between pairs of transistors to be compensated for by the addition of trimmer potentiometers: the idea has been tested in simulation using Simetrix. The second circuit extract shows the required changes.
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Wednesday, October 29, 2014

LM1875 20W audio amplifier Diagram Circuit

Description.
This is just another 20W audio amplifier circuit , but this time based on the LM1875 audio amplifier IC from National Semiconductors. With a 25V dual power supply LM1875 can deliver 20W of audio power into a 4 ohm speaker. The LM1875 requires very less external components and has very low distortion. The IC is also packed with a lot good features like fast slew rate, wide supply voltage range, high output current, high output voltage swing, thermal protection etc. The IC is available in TO-220 plastic power package and is well suitable for a variety of applications like audio systems, servo amplifiers, home theatre systems etc.
Circuit diagram.

Notes.
 lm1875 20w audio amplifier circuit and explanation
  • Assemble the circuit on a good quality PCB.
  • Use +/-25V DC dual supply for powering the circuit.
  • K1 can be 4 ohm, 20W speaker.
  • A proper heat sink is necessary for the IC.
  • F1 and F2 are 2A fuses.
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SUPER EAR

This circuit is a very sensitive 3-transistor amplifier using a speaker transformer. This can be wound on a short length of ferrite rod as show above or 150 turns on a 10mH choke. The biasing of the middle transistor is set for 3v supply. The second and third transistors are not turned on during idle conditions and the quiescent current is just 5mA.

The project is ideal for listening to conversations or TV etc in another room with long leads connecting the microphone to the amplifier.


source : http://www.talkingelectronics.com.au/projects/200TrCcts/200TrCcts.html
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USB Powered Audio Power Amplifier Circuit Diagram

This is the simple USB Powered Audio Power Amplifier Circuit Diagram. This circuit of multimedia speakers for PCs has single-chip-based design, low-voltage power supply, compatibility with USB power, easy heat-sinking, low cost, high flexibility and wide temperature tolerance. At the heart of the circuit is IC TDA2822M. This IC is, in fact, mono-lithic type in 8-lead mini DIP package. It is intended for use as a dual audio power amplifier in battery-powered sound players. Specifications of TDA2822M are low quiescent current, low crossover distortion, supply voltage down to 1.8 volts and minimum output power of around 450 mW/channel with 4-ohm loudspeaker at 5V DC supply input. 

An ideal power amplifier can be simply defined as a circuit that can deliver audio power into external loads without generating significant signal distortion and without consuming excessive quiescent current. This circuit is powered by 5V DC supply available from the USB port of the PC. When power switch S1 is flipped to ‘on’ position, 5V power supply is extended to the circuit and power-indicator red LED1 lights up instantly. Resistor R1 is a current surge limiter and capacitors C1 and C4 act as buffers. Working of the circuit is simple. Audio signals from the PC audio socket/headphone socket are fed to the amplifier circuit through components R2 and C2 (left channel), and R3 and C3 (right channel).

Circuit diagram:



USB Powered Audio Power Amplifier Circuit Diagram

Potmeter VR1 works as the volume controller for left (L) channel and potmeter VR2 works for right (R) channel. Pin 7 of TDA2822M receives the left-channel sound signals and pin 6 receives the right-channel signals through VR1 and VR2, respectively. Ampl i f ied signals for driving the left and right loudspeakers are available at pins 1 and 3 of IC1, respectively. Components R5 and C8, and R6 and C10 form the traditional zobel network. Assemble the circuit on a medium-size, general-purpose PCB and enclose in a suitable cabinet. It is advisable to use a socket for IC TDA2822M. The external connections should be made using suitably screened wires for better result.



Sourced By: EFY
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Contrast Control for LCDs

The adjustment control for the contrast of an LC-Display is typically a 10-k potentiometer. This works fine, provided that the power supply voltage is constant. If this is not the case (for example, with a battery power supply) then the potentiometer has to be repeatedly adjusted. Very awkward, in other words. The circuit described here offers a solution for this problem. The aforementioned potentiometer is intended to maintain a constant current from the contrast connection (usually pin 3 or Vo) to ground.

A popular green display with 2x16 characters ‘supplies’ about 200 µA. At a power supply voltage of 5 V there is also an additional current of 500 µA in the potentiometer itself. Not very energy efficient either. Now there is an IC, the LM334, which, with the aid of one resistor, can be made into a constant current source. The circuit presented here ensures that there is a current of 200 µA to ground, independent of the power supply voltage. By substituting a 2.2-k? potentiometer for R1, the current can be adjusted as desired.

Circuit diagram:The value of R1 can be calculated as follows: R1 = 227x10-6 x T / I. Where T is the temperature in Kelvin and I is the current in ampères. In our case this results in:
R1 = 227x10-6 x 293 /
(200x10-6)
R1 = 333R
Note that the current supplied by the LM334 depends on the temperature. This is also true for the current from the display, but it is not strictly necessary to have a linear relationship between these two. Temperature variations of up to 10° will not be a problem however. This circuit results in a power saving of over 25% with an LCD that itself draws a current of 1.2 mA. In a battery powered application this is definitely worth the effort! In addition, the contrast does not need to be adjusted as the battery voltage reduces. When used with LCDs with new technologies such as OLED and PLED it is advisable to carefully test the circuit first to determine if it can be used to adjust the brightness.

Circuit diagram:

Contrast Controller Circuit Diagram For LCDs

The value of R1 can be calculated as follows: R1 = 227x10-6 x T / I. Where T is the temperature in Kelvin and I is the current in ampères. In our case this results in:
  • R1 = 227x10-6 x 293 /
  • (200x10-6)
  • R1 = 333R
Note:
  • The current supplied by the LM334 depends on the temperature. This is also true for the current from the display, but it is not strictly necessary to have a linear relationship between these two. Temperature variations of up to 10° will not be a problem however. This circuit results in a power saving of over 25% with an LCD that itself draws a current of 1.2 mA. In a battery powered application this is definitely worth the effort! In addition, the contrast does not need to be adjusted as the battery voltage reduces. When used with LCDs with new technologies such as OLED and PLED it is advisable to carefully test the circuit first to determine if it can be used to adjust the brightness.
Author: Heino Peters
Copyright: Elektor Electronics
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Tuesday, October 28, 2014

Automatic Emergency Lamp Circuit

This is an automatic emergency lamp with day light sensing, means it senses darkness/night and turns ON automatically. Similarly it senses day light and turns OFF automatically. A simple emergency lamp which does not require any special equipment; even a multimeter to assemble and use. Any individual who can do a good quality soldering must be able to build this circuit successfully.

This can be easily accommodated in the defunct two 6 watt tube National Emergency Lamp or any PL tube type emergency lamp. The difference will be in the working; it will work non stop for more than 8 hours. Deep discharge is taken care by the LED characteristic and over charge protection is taken care by the fixed voltage regulator.This uses a simple 3Pin fixed regulator which has a built in current limiting circuit.

Simple Emergency Light Circuit Diagram: 

Automatic
Automatic Emergency Lamp Circuit
The only required adjustment is the preset which has to be set to ensure the LEDs just light up (it should be left at that position). The 5mm LDR is just mounted on top of the emergency light as shown in the photograph. LDR is used to avoid it lighting up during day time or when the room lights are ON. 2 LEDs are used in series; the dropping resistance is avoided and 2 LEDs light up with current that is required for a single LED,  by which energy is saved to a great extent.

This particular circuit has been kept so simple for people who has limited access to components or in other words this is an emergency light that you can build with minimum components. In addition to circuit diagram, He has shared photographs of the prototype he made in National emergency light and a PCB design.
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400Watt IRFP448 Power Amplifier

Power amp 400W IRFP448 Circuit
Amplifier circuit these days,We would like to musical you pro the MOSFET 400 watt amplifier is amplifier on my kW shares the same circuit and main PCB design. The barely real difference is the figure of output procedure to the device. We encompass using The IRFP448 design while the MOSFET amplifier 14 O / P procedure. These amplifiers can live used used for almost a few effort with the aim of requires in height performance, low apply din, distortion and brilliant sound quality. Examples would be subwoofer amplifier be supposed to FOH stage Amplifiers, surround a inland waterway a very powerful sound amplifier, et cetera. The 400W MOSFET-amplifier has four tone stages of amplification. We are looking to start several   stage appropriate list.

400Watt IRFP448 Power Amplifier Circuit Diagram


The bias and bumper stage
in the role of the entitle suggests All Q ,C and ZD the Bias and buffer phases. Its major goal is to provide a firm MOSFET Gates  and offset voltage and the voltage memory amplifier stage of the extraordinary Resource scope. pardon? would engage in devoid of the period response and the effect Slew rate is indeed very bad. The flip part of the coin is not the spare step Introduction of an bonus dominant pole trendy the amplifier opinion disk.

Power amp 400W IRFP448 PCB and  the electronic components layout thus as below :

PCB layout design

Component Placement
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Op Amp Sound Module wit IC741

This is due to the IC Acting Analog amplifiers. Mainly commonly used is the IC Op-Amp reduced. Is a valuable slew rate low. It can not know the immediate modification of the digital motion. The frequency response is not expansive adequate. Makes the sound move toward impossible with distinct and harsh. We need to arrange with an analog output amplifier with peak efficiency. And a filter wearing glut of excessive. To eliminate the sharp sound.So this circuit. must elite the IC op amp with high quality. To follow a significance LEWIS Garrett with a high and expensive. The circuit is not the numeral IC op amp to live used depending on demand.
Op-Amp Sound Module wit IC741 Circuit Diagram
Whilst raising the power supply circuit, the power sector through candid loans isolates. Consisting of Q1, Q2, ZD1, ZD2, R5, R6, C10 and C11. The circuit Direct loans segregate the control voltage in support of supplying the integrated circuit is on 12V and-12V. The C5-C9 is a radio dish. bypass capacitor. Help indoors responding to exalted frequencies and reduce the leak of the capacitor electronic highlighting of C4 and C3. while the input to the pin 3 bedroom inverse proper IC1 to delay motion not to period improbable the. Pin 6 and the signal part is fed back through R3 and R2. which is 1.3 epoch the growth rate C1 and C2 play a part to eliminate high frequency redundant. This circuit is a circuit with the intention of extends the ordinary. The rule that the resistance of the circuit high input, to prevent the loading of the amplifier’s first album. And a low output resistance, so they can drive oodles without difficulty. The sound quality to tolerate come up to shown that is based on the IC op-amps used IC op-amp must take the elevated slew rate opamp.

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Monday, October 27, 2014

300W Power Amplifier Circuit with 2N773

Power Amplifier 300W with transistor 2N3773
This amplifier was designed to provide a use for the otherwise useless TO3 power transistors that many hobbyists have in their junk pile.  With good construction the module is capable of high quality performance and is rated to 300 watts into a 4 ohm load depending on power supply.  With the driver and output transistors specified it is limited to DC rails of +/- 70 volts. 

Power Amplifier Circuit Diagram

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Lm318 Microphone preamplifier with tone control Diagram Circuit

This electronic project is a simple microphone preamplifier based on the LM318 op amp . The LM318 op amp is operated as a standard non-inverting amplifier. Resistor R1 provides an input path to ground for the bias current of the non-inverting input. The combination of R2 and C2 provides a frequency roll-off below 30 Hz. At 30 Hz and above the gain is relatively flat at about 50 dB, set by the ratio R3/R2. R3 furnishes negative feedback from the output to the inverting input of the op amp. C3 ac couples the preamp to the tone control section.
The top half of the tone control section is the bass control. The bottom half controls the treble frequency response. These tone controls (R5 and R8) require audio taper (logarithmic) potentiometers. The 50 k ohm potentiometer on the output can be used to set the output or gain of the preamp .

The circuit is very simple and require few electronic parts . This microphone preamplifier electronic project must be powered from a dual 15 volt DC power supply .
If you don’t want to use tone control function for the microphone preamplifier you can eliminate the tone control part from the project .
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Power Supply Failure Alarm

Most of the circuit power supply failure alarm circuits require additional or external power supply. However, this circuit requires no additional power supply. The circuit uses a voltage of 5 volts to 15 volts. To adjust the voltage of this circuit, first connect the power source (5 to 15V) and change the position of potentiometer VR1 until the buzzer buzzer On to Off position.
If the power supply fails, resistor R2 will bias the transistor and the base will turn on the buzzer. Here is a picture series of power supply failure alarm :
 power supply failure alarm
 Power Supply Failure Alarm  Circuit

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40 Watt Fluorescent Lamps Diagram Schematics

This is a Circuits of fluorescent lamp with a power of 40 Watt - The ambit works abundant like the aboriginal Strobos. except that a beaming tube is used. Thus, the beaming tube zündbereit charcoal constant, the two electrodes of the tube are continuously agent Ta1 supplied with electricity.
Click To view larger | 40 Watt Fluorescent Lamps Diagram Schematics

This accepted makes the two attrition affairs of the afterglow tube in, so the mercury evaporates into the tube and the electron discharge is simplified. Ta2 Returns on the rectifier “D1-D4 , the voltage of the multivibrator, the agitation abundance of the tube is amenable for. The acceleration of the AMV is with potentiometer P1 set. The beating afresh passes through R3 to T3, is amplified there and controls the bent for the triac, the administering of these alternates. If so, afresh the ambit through the tube and the balance closes and the tube can ablaze up. 

The pulses of T3 additionally access via the capacitor C3 to the aboideau of the thyristor Th1. Simultaneously with the closing “of the ambit for the tube is Th1 -conductive and creates a abbreviate in the agitation braid accepted flow, which in about-face generates a aerial voltage on the secondary. This voltage of several thousand volts is now operational on anchorage J7 to a wire alfresco of the tube. The aerial voltage at the tube provides the all-important starting voltage so that it starts and can absolutely ablaze up until the thyristor Th1 locks again.

Part List:

C1/C2 2x  Elco standing 1μF/16V
C3 1x  Ker. Scheibenkondens. 0.1 μF
C4 1x  HV-capacitor 1μF 350V axial
C5 1x  Elko stand. 470μF 25 V
C6 1x  Poly condensation. 0.068 μF 630V
D1-4 4x  Diode 1N4001
D5 1x   Diode 1N4007
L1 1x  Ignition coil (such as the normal speed camera strobe)
P1 1x  Poti 6mm 2.2 M
R1/R4 2x  Resistor 470R 1 / 4 W
R2/R9 2X  Resistor 47K 1 / 4 W
R3 1x  Resistor 10K 1 / 4 W
R5 1x  Resistor 270R 1 / 4 W
R6 1x  Resistor 1.2 K 1 / 4 W
R7 1x  Resistor 22K 1 / 4 W
R8 1x  Resistor 120K 1 / 4 W
Si1 1x  Backup medium time 160mA
Si2 1x  A pair of fuse holders
T1/T2 2x  Transistor BC557B
T3 1x  Transistor BC547B
Ta1 1x  Transformer 2x 2x 5V 500mA 5VA
TA2 1x  Trafo 1,2 VA 9Volt
Th1 1x  Thyristor 4A 400V T0220
TR1 1x  Triac 4A 400V T0220

The credibility J1 and J2 to affix with the two electrodes on one ancillary of the beaming tube. The credibility J3 and J4 , affix with the electrodes on the added side. Now amplitude a attenuate insulated!! Wire forth the tube and cement it eg. Scotch band firmly. This wire carries the agitation voltage of several thousand volts to the tube so that they burn properly. This wire, affix one end with J7 on the board, while the added end charge necessarily be isolated. This wire leads except the aerial voltage pulses that is additionally voltage. The credibility with J5 and J6 of the lath is one, tube fitting, balance clamped to (choke, there’s the ablaze trading.) Finally there is the voltage at J8 and J9. Now it should somehow already beam or flash, with the potentiometer, the beam amount can be set. 
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Sunday, October 26, 2014

Line Follower Robot Sensor Concept

Line Follower Robot Sensor Concept - Sensor line detector is used in line follower robot is usually based on the principle of light reflectionto distinguish the line with the background color. In the dark color of the light absorption is greater than that of white light reflected to the sensor becomes smaller.
Position sensor to track the trajectory and the example circuit.

Line Follower Robot Sensor Concept
Light used for the introduction of the line is usually visible light and infra-red. Sensors for visible light are commonly used are LDR (Light Depending Resistance), while for the infrared light is atransistor and photo diode (photodiode). Sensors placed at the bottom of the frame to hang the robot, so that its position can be located just above the track to be read.

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IC 741 Simple High Pass Filter


This be Simple high pass Filter perform filter especial tall frequency can change only. By use IC 741 , be the integrated circuit op-amp very the circuit helps to are high frequency Filter model to be simple. By from the circuit will let 750 HZ frequencies s go up change more well , 60HZ frequencies are or lower. By friends can change the value RC for filter the frequency that can want which can see the detail has followed circuit picture yes.
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Saturday, October 25, 2014

Solar Relay circuit diagram and explanation

With extended periods of bright sunshine and warm weather, even relatively large storage batteries in solar-power systems can become rather warm. Consequently, a circuit is usually connected in parallel with the storage battery to either connect a high-power shunt (in order to dissipate the excess solar power in the form of heat) or switch on a ventilation fan via a power FET, whenever the voltage rises above approximately 14.4 V. However, the latter option tends to oscillate, since switching on a powerful 12-V fan motor causes the voltage to drop below 14.4 V, causing the fan to be switched off.

In the absence of an external load, the battery voltage recovers quickly, the terminal voltage rises above 14.4 V again and the switching process starts once again, despite the built-in hysteresis. A solution to this problem is provided by the circuit shown here, which switches on the fan in response to the sweltering heat produced by the solar irradiation instead of an excessively high voltage at the battery terminals. Based on experience, the risk of battery overheating is only present in the summer between 2 and 6 pm. The intensity of the sunlight falling within the viewing angle of a suitably configured ‘sun probe’ is especially high precisely during this interval.

This is the operating principle of the solar relay. The trick to this apparently rather simple circuit consists of using a suitable combination of components. Instead of a power FET, it employs a special 12-V relay that can handle a large load in spite of its small size. This relay must have a coil resistance of at least 600 Ω, rather than the usual value of 100-200 Ω. This requirement can be met by several Schrack Components relays (available from, among others, Conrad Electronics). Here we have used the least expensive model, a type RYII 8-A printed circuit board relay. The light probe is connected in series with the relay. It consists of two BPW40 phototransistors wired in parallel.

Solar
Solar Relay Circuit Diagram

The type number refers to the 40-degree acceptance angle for incident light. In bright sunlight, the combined current generated by the two phototransistors is sufficient to cause the relay to engage, in this case without twitching. Every relay has a large hysteresis, so the fan connected via the a/b contacts will run for many minutes, or even until the probe no longer receives sufficient light. The NTC thermistor connected in series performs two functions. First, it compensates for changes in the resistance of the copper wire in the coil, which increases by approximately 4 percent for every 10 ºC increase in temperature, and second, it causes the relay to drop out earlier than it otherwise would (the relay only drops out at a coil voltage of 4 V).

Depending on the intended use, the 220-Ω resistance of the thermistor can be modified by connecting a 100-Ω resistor in series or a 470-Ω resistor in parallel. If the phototransistors are fastened with the axes of their incident-angle cones in parallel, the 40-degree incident angle corresponds to 2 pm with suitable solar orientation. If they are bent at a slight angle to each other, their incident angles overlap to cover a wider angle, such as 70 degrees. With the tested prototype circuit, the axes were oriented nearly parallel, and this fully met our demands. The automatic switch-off occurs quite abruptly, just like the switch-on, with no contact jitter.

This behaviour is also promoted by the NTC thermistor, since its temperature coefficient is opposite to that of the ‘PTC’ relay coil and approximately five times as large. This yields exactly the desired effect for energising and de-energising the relay: a large relay current for engagement and a small relay current for disengagement. Building the circuit is actually straightforward, but you must pay attention to one thing. The phototransistors resemble colourless LEDs, so there is a tendency to think that their ‘pinning’ is the same as that of LEDs, with the long lead being positive and the short lead negative. However, with the BPW40 the situation is exactly the opposite; the short lead is the collector lead. Naturally, the back-emf diode for the relay must also be connected with the right polarity. The residual current on cloudy days and at night is negligibly small.
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Friday, October 24, 2014

1500W HiFi Power Amplifier Circuit

Circuit Power Amplifier has a power output of up to 1500W RMS, power amplifier circuit is often used to power sound systems needed to outdor. In a series of images can be seen the final power amplifier uses 10 sets of large power transistors for the ending.
This power amplifier circuit using a transistor amplifier starting from the front, signal splitter, driver and power amplifier. Current consumption required is quite large power amplifier that is 15-20 A for this 1500W power amplifier circuit. Supply voltage needed by the power amplifier in order to work optimally is symmetrical 130VDC (130VDC ground-+130 VDC). 1500W amplifier circuit below is a picture series of mono, if you want to create a stereo it is necessary to make 2 copies of the circuit. For more details can be viewed directly image following a series 1500W power amplifier.

1500W HiFi Power Amplifier with Transistors



In the above series 1500W power amplifer has been equipped to control the DC Offset function to set the power amplifier when turned on and no input signal then the output should 0VDC. Then it is also equipped with a bias flow regulator to the power amplifier. The final power amplifier section requires that sufficient coolant to absorb heat generated. Power amplifier is not equipped with speakers protectors, therefore it should diapsang speaker protector on the output for when the power amplifier is turned on does not happen the beat to the speakers that may damage the speaker.
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Powerful Battery Charger Circuit

Series NIMH Battery Charger with IC LT4060 is a NIMH battery charger is powerful, effective and efficient. Featur owned by IC LT4060 is a specialization of a NIMH battery charger. NIMH Battery Charger with IC LT4060 can perform safely charging NIMH batteries because it comes with a battery temperature protection is in charge and the peak level detection system of the battery voltage is in charge. 
Battery temperature protection system from the excessive use of NTC temperature sensor. Series NIMH Battery Charger with IC LT4060 also features a charging indicator that will light up when charging and will die when the battery is full. IC 4060 used in this NIMH battery charger from Linear Technology is a production that is designed special for NIMH battery charger.

Image Series NIMH Battery Charger with IC LT4060

Description Series NIMH Battery Charger with IC LT4060
R2 potentiometer used for setting the maximum temperature (at set at the value of 4K)
LED D1 is a battery charging indicator
Charger Power Transistor (Q1) can be replaced with PNP transistors are capable of a current of 3A - 5A
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Thursday, October 23, 2014

Fire alarm with light sensor

Fire alarm can be made with a light sensor (LDR) as in the article with the title of Fire Alarm with this LDR sensor. Principles of fire detection Fire Alarm with LDR sensor is to detect the presence of smoke through the LDR. LDR in the series Fire Alarm does not stand alone in detecting a fire, but the LDR in the pair with the light shining on the LDR.

Hence, in the detected smoke from the fire then the intensity of light received by the LDR LDR decreases and eventually trigger an alarm system on a series of Fire Alarm with this LDR sensor. Part 2 that in the series of Fire Alarm with Sensor LDR are some of the sensors, tone generator, audio power.


Image Series Fire Alarm with Sensor LDR


Function Section of the Fire Alarm with Sensor LDR
Part of LDR and light sensor facing to fire smoke detection
Part trigger using transistors and regulators as a trigger tone generator 7805
Tone generator section with IC UM66
Power audio section uses an audio power IC TDA 2002 which is equipped with voleme control (R3)
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Radio Control for toy car

Radio Control for toy car
Play toy cars controlled by radio signals is an interesting game. The much-loved toy cars children, plus a simple circuit would be ideal for toy cars. This series of families use traditional digital CMOS IC which requires a very small electric current, so it does not impose on the performance of the original toy cars.
In this system, radio signals emitted not continuously but only generated when the controller sends a command left / right or forward / backward, and even then only a radio frequency of an intermittent, so it is sending pulses of radio wave frequency.
Number of pulses sent represents a command is sent, the command GO is represented by 8 pulses, represented by 16 pulses LEFT, RIGHT DOWN 32 pulses and 64 pulses. Command sent to a combination of two orders once gus, which is a combination of command forward / backward and right / left, for example, could be sent forward command and left once gus, in this case the number of pulses sent is 24, which is the sum of the forward command command as much as 8 pulses and left as many as 16 pulses.
Once a command is sent, the system stops sending commands in a certain time lag, the lag time it takes the receiver circuit will have sufficient time to execute properly. Frequency pulses were visible on the right side of Figure 1.

How it works The transmitter
Radio signals generated by the oscillator circuit formed by transistors Q1 9016, the working frequency of the oscillator is determined by the crystal Y1 is worth 27.145 MHz. A very critical part of this oscillator circuit is T1, L1 and L2, which specifically dealt with separately at the end of this article.
Work of the oscillator is controlled by a NOR gate U2D 14001, while the output gate (pin 3) is worth 1 , the oscillator will work and transmit radio frequency 27.145 MHz, and at the output U2D value 0 the oscillator will stop working.
U2D NOR gate receives the clock signal from the NOR gates U2B. NOR gate CMOS type with the help of resistors R4 and R5 and capacitor C8 to form a low frequency oscillator circuit to control the clock shaper of existing digital circuits. Working from the clock generator is controlled via the input leg 6, the circuit will generate the input clock that is berlevel 0 .
NOR gate U2A and U2C form a latch circuit (RS Flip Flop), due to the influence of resistor R2 and capacitor C11 which is fed to pin 9 on U2C, when the circuit gets power supply output U2C must be 1 and U2A output (pin 3) to 0 . This situation resulted EUIS clock generator generating a clock U2B work and release the reset state of the enumerator 14 024 IC (U1), so that the U1 start chopping and 27.145 MHz oscillator circuit to send pulses of the clock generator frequency during work.
At the start chopping, all the output IC 14 024 enumerators in kedaan 0 , after chopping the 8 pulse output Q4 (pin 6) will be 1, after chopping 16 Q5 pulse output (pin 5) to 1 , after chopping 32 Q6 output pulse (pin 4) to 1 , after 64 counts pulses output Q7 (pin 3) to 1.
Outputs are used to control the voltage above 9 feet U2C through diode D1 and D2, as long as it remains one of the output value 0 then the plant U2B clock still works, it will continue until dankatode D2 D1 cathode to 1 so that the foot 9 U2C a 1 as well. This situation will lead to 3 feet U2A output to 1 , which stops the clock generator and reset U2B enumerator 14 024 danberhenti is sending pulses of frequency 27 145 MHz.
To generate the lag time for the receiver circuits have enough time to perform the command, used a series of 9014 Q2, the resistor R7 and capacitor C10. The magnitude of the delay time is determined by the value of R7 and C10. The switch to send the command forward / backward and to send the command left / right are two separate switches. Each switch has three positions, the center position means that the scalar does not send commands.
How It Works Recipients
Figure 2 is a recipient of a series of paired images dimobil toy, serves to receive signals from the transmitter to control the motor cars, so cars can move forward / backward and left / right. Transistor Q1 with the help of resistors; capacitors and T1 form as a series of 27.145 MHz radio signal receiver. T1 in series with a T1 is exactly the same used in the transmitter circuit, how to make it are discussed below.
Transistor Q2 perlangkapannya formed following a series of pulses to change the radio frequency received from the transmitter into the box pulses that can be accepted as a digital signal by the CMOS IC. Digital signal will be received as the clock had to be chopped by enumerator 14 024 IC (U2). Output of 14 024 would correspond to the number of pulses sent by the transmitter, forward command and left (which is used as an example in the discussion of the transmitter) is the pulse number of 24, the enumeration of these pulses resulted in 14 024 to be output Q4 = 1 , Q5 = 1, Q6 = 0 and Q7 = 0.
The received digital signal other than U2 used as counter clock IC 14 024 discussed above, is also used to move the 3 pieces of the time delay circuit to generate pulses which controls the sequence of work.
The first control pulse will appear after submission frequency pulse stopped because the lag time between sending the code, this pulse count function to record the results of 14 024 to 14 042 U3 (D Flip Flop), so that the final condition of 14 024 will be retained to control the motor. After the results were recorded for 14 024 14 042, 14 042 counter is reset by the second pulse, so that after the lag time counter counts up starting from 14 042 to 0 again.
Circuit formed by transistors Q3, Q4, Q7, Q8, Q9 and Q10 H Bridge is named as a series, this series is very powerful to drive the DC motor. With this circuit the DC motor can be rotated to the right-to-left or stop motion. The main requirement is the use of this circuit Q7 and the base voltage of Q10 base voltage must be opposed, for example, the base Q7 = 1 and the base of Q10 = 0 motor rotates to the left, the base of Q7 = 0 and the base of Q10 = 1 motor will turning to the right, the base Q7 = 0 and Q10 base = 0 motor stop motion, but should not be happening base Q7 = 1 and the base Q10 = 1.
Similarly, Q5, Q6, Q11, Q12, Q13 and Q14 form an H Bridge. H Bridge to the left in Figure 2 is used to control a motor that regulates the movement of cars left / right, while the H Bridge to the right is used to control a motor that regulates the movement forward / backward cars.
The relationship between outpur enumerator 14 042 and input D Flip Flop 14 024 is arranged such that the signal is fed to each of the H Bridge can not be all 1 simultaneously.


Manufacture of transformer TX and RX
Transformer T1 in the series transmitter and receiver, is the same stuff, and have made ​​themselves. Transformer was built using a plastic transformer Koker (spare part radio) that has a step that appears 5 lines that can be filled with coils of wire, as shown in the photograph. Wearing this Koker facilitate wire transformer windings. Otherwise it could be similar Koker, just the usual wear. Koker is a small transformer and feritnya also small (3 mm) as that used to be used for the assembly of CB 27 MHz radio.
Can wear a wire to wire the transformer in the unloading of Koker, carefully open coil of wire that already exist in the Koker because the wire is quite smooth and quite easy to break.
Step 1: rolls of wire which is numbered 5 feet to 4 feet in the direction of h (CW) for 3 rolls right on level 1 (pathway level above the bottom line)
Step 2: Roll the wire from 1 foot to 2 feet in a clockwise direction as much as 4 rolls right on level 2.
Step 3: Continue the roll (from step 2) in a clockwise direction as much as three quarter roll to 3 feet on three levels. (Can be determined exactly a quarter of the roll, because it has a track kokernya split into 4).
Manufacture of coil L1
Roll of copper wire diameter from 0.3 to 0.5 mm by 10 quarter rolls on Koker diameter of about 4 mm (which will be released) is also in a clockwise direction.
Manufacture of coil L2
Roll of copper wire 0.1 mm diameter by 50 rolls in plastic Koker without ferrite diameter of about 3.5 - 4 mm (look for the plastic material from scrap) is also in a clockwise direction. Long section on liputi rolls along the 5 mm.
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IC M3481 Music box versatile

This is a multi-purpose integrated music box that interesting, because an IC package. Is a simple and affordable.
The main function of the circuit is the device of the circuit is IC1. This is a sound generator IC. The Christmas season. Its musical all 8 music. When the power supply LDR1 the exposure will cause voltage drop across R1 is enough to make IC1 work has output to stimulate pin 11 and pin 12 to stimulate pin B of Q1. Q2 and the current expansion drive that will be the speaker.

While the circuit work if the switch S1 connected to the unique music tracks and so on, but if S1 is not connected. Circuit will play all the songs. If the switch S2 connected to the cycle When there is no light will stop play immediately. But if the switch S2 is not connected to music and no light will not stop until the song is finished playing. Switch S3 is responsible for selecting music on, press 1 once one moves to music. The VR1 is also a tone control if VR1 is less resistance will be reduced to a lower tone. And the music will slow down play with. The R6, C3 is responsible for smooth sound more R7 forward to control the feedback stability of dc output of the circuit.

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Wednesday, October 22, 2014

200 Watt Power Amplifier STK4050 STK4046

Amplifier circuit with IC STK is tough and good quality. In this article an amplifier circuit with IC STK another base. Power "Amplifier 200Watt By STK4050" is an audio amplifier of the STK family with 200Watt power. To create a power amplifier with the STK4050 IC is not require many external components.

Power Amplifier uses symmetric 30Volt power supply system. Power Amplifier With this STK4050 can reproduce the power 200 Watts at 8 Ohm load spaker. In making Power Amplifier 200Watt With this STK4050 do not forget to provide adequate heat sink for the IC STK 4050 in order to avoid overheating.


Schematics Amplifier STK4050-STK4046


PCB Layout Amplifier

Series Power Supply for Power Amplifier 200Watt By STK4050 been displayed in one image with a series of "Power Amplifier" 200Watt With STK4050 above. IC STK 4050 in this series there are several types on the market including STK4050II, STK4050V and STK4050.

And below is a list of STK ICs are used for a good quality amplifier.

Datasheet STK IC Amplifier
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Saturday, October 18, 2014

1 to 999s with PIC16F84A Timer from

This is a good looking and practical device that can be useful in many areas where countdown timer is needed. This project is based on the PIC16F84A microcontroller. The time range can be adjusted between 1 and 999 seconds.   This project  has 3 buttons and one of them is named Set Button. In order to regulate the seconds up or down  on the display you should press the Set button while pressing the button on the  left or the right  hand side. The author of this project is @Pedja089. More photos on Facebook Fan Page.
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ICM7556 Car Boot Lamp Warning circuit and explanation

On many cars, the boot light will not go out until the lid is properly closed. It is all too easy when unloading the car, to leave the lid ajar. If you are unlucky and the car remains unused for some time, the next time you try to start it, the lamp will have drained the battery and you will no doubt utter a few appropriate words. The circuit described here will give a warning of just such a situation. A mercury tilt switch is mounted in the boot so that as the lid is closed, its contacts close before the lid is completely shut. The supply for the circuit comes from the switched 12 V to the boot lamp and through the mercury switch. When the lid is properly closed, the boot lamp will go out and the supply to the circuit will go to zero. If however the lid is left ajar, the lamp will be on and the mercury switch will close the circuit.

CarAfter 5 seconds, the alarm will start to sound, and unless the lid is shut, it will continue for 1 minute to remind you to close the boot properly. The 1-minute operating period will ensure that the alarm does not sound continuously if you are, for example, transporting bulky items and the boot will not fully close. The circuit consists of a dual CMOS timer type 7556 (the bipolar 556 version is unsuitable for this application). When power is applied to the circuit (i.e. the boot lid is ajar) tantalum capacitors C1 and C2 will ensure that the outputs of the timers are high. After approximately 5 seconds, when the voltage across C2 rises to 2/3 of the supply voltage, timer IC1b will be triggered and its output will go low thereby causing the alarm to sound.

Meanwhile the voltage across C1 is rising much more slowly and after approximately 1 minute, it will have reached 2/3 of the supply voltage. IC1a will now trigger and this will reset IC1b. The alarm will be turned off. IC1a will remain in this state until the boot lid is either closed or opened wider at which point C1 and C2 will be discharged through R6 and the circuit will be ready to start again. To calculate the period of the timers use the formula: t = 1.1RC Please note that the capacitor type used in the circuit should be tantalum or electrolytic with a solid electrolyte. The buzzer must be a type suitable for use at D.C. (i.e. one with a built in driver).
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FM transmitter schematic

fm transmitter schematic, PC board pattern, and parts placement for a low powered FM transmitter. The range of the transmitter when running at 9V is about 300 feet. Running it from 12V increases the range to about 400 feet. This transmitter should not be used as a room or telephone bug.

parts


Notes

L1 and L2 are 5 turns of 28 AWG enamel coated magnet wire wound with a inside diameter of about 4mm. The inside of a ballpoint pen works well (the plastic tube that holds the ink). Remove the form after winding then install the coil on the circuit board, being careful not to bend it.

C5 is used for tuning. This transmitter operates on the normal broadcast frequencies (88-108MHz).
Q1 and Q2 can also be 2N3904 or something similar.
You can use 1/4 W resistors mounted vertically instead of 1/8 W resistors.
You may want to bypass the battery with a .01uf capacitor.
An antenna may not be required for operation.
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Friday, October 17, 2014

Simple OBD Vehicle Protection

Vehicle immobilisers are fitted as standard to modern cars and heavy goods vehicles. Anti-theft mechanisms have become more sophisticated but so have the methods employed by crooks. Nowadays once the thief has gained access to a vehicle they will most likely use an electronic deactivation tool which seeks to disable the immobiliser, once this has been accomplished a blank transponder key/card can be used to start the engine. In many cases communication with the immobiliser is made using the OBD-II diagnostic connector.

Although the OBD-II protocol itself does not support the immobiliser, the vehicle manufacturer is free to use the interface as neces-sary for communication, either the standard OBD-II signals or unused pins in the OBD-II connector (i.e. those undefined in the OBD-II standard). Using one of these pathways the immobiliser can usually be electronically disabled. 

OBD Vehicle Protection Circuit Diagram
This may be unsettling news for owners of expensive vehicles but when professional car-thieves call, armed with the latest OBD-II hacking equipment this simple low-cost low-tech solution may be all that you need. The idea is ver y simple: if all connections to the OBD-II connector are disconnected there is no possibility for any equipment, no matter how sophisticated to gain access via the vehicle’s wiring. 

The OBD-II connector is usually locate d underneath the dashboard on the passenger side; once its wiring loom has been identified a switch can be inserted in line with the wires. The switch should be hidden away some-where that is not obvious. In normal opera-tion you will be protected if the vehicle is run with the wires to the socket disconnected. Make sure however that you throw the switch reconnecting the socket before you next take the vehicle along to a garage for servicing or fault diagnosis. 

The diagram shows the ISO K and ISO L wires switched. To cover all bases it is wise for every wire to the socket is made switchable except the two earth connections on pins 4 and 5 and the supply voltage on pin 16. Almost ever y vehicle manufacturer has their own method of vehicle immobilisation, by disconnecting every wire it ensures that no communication is possible (even over the CAN bus). Now the innermost workings of your vehicle will be safe from prying eyes. When a hacker plugs in a deactivation tool it will power up as normal but probably report something like ‘protocol unrecognised’ when any communication with the OBD port is attempted.

Author : Florian Schäffer - Copyright: Elektor
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Cmos 4047 Power inverter 12Vdc to 220Vac circuit and explanation


This converter has a central component, the CMOS 4047, and converts a 12V DC voltage to 220V AC voltage. 4047 is utilised as a astable multivibrator. At pin 10 and 11 we find a rectangular symmetrically signal which is amplified by tow Darlington transistors T1 and T2 and finally reaches the secondary coil of a transformer network (2 x 10V/60VA). Primary coil terminals voltage is 220 alternative voltage. To obtain a better performance use a toroidal core transformer with reduced losses. With P1 the output frequency can be regulated between certain limits (50…400Hz). 
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Digital Electronics List of 7400 series TTL Integrated Circuits

 
Digital
The 7400 series of TTL integrated circuits originated with Texas Instruments. Owing to its great popularity were produced by thousands of manufacturers around the world, keeping the original series marking 7400, thus became even more popular and easier compatibility.

List of TTL integrated circuits 7400 series


7400 - Four two-input NAND gates
7401 - Four two-input NAND gates with open collector
7402 - Four two-input NOR gates
7403 - Four two-input NAND gates with open collector
7404 - Six- NOT gates
7405 - Six NOT gates with open collector outputs
7406 - Six Buffer / Driver 30V inverters with outputs open collector
7407 - Six Buffer / Driver with 30V outputs with open collector
7408 - Four two-input AND gates
7409 - Four two-input AND gates with open collector
7410 - Three NAND gates with three inputs
7411 - Three AND gates with three inputs
7412 - Three of three inputs NAND gates with open collector
7413 - Two NAND gates four Schmitt trigger inputs
7414 - Six Schmitt trigger inverters
7415 - Three AND gates with open collector three entries
7416 - Six Buffer / Driver 15V inverters with outputs open collector
7417 - Six Buffer / Driver with 15V output with open collector
7419 - Six Schmitt trigger inverters
7420 - Two four-input NAND gates
7421 - Two four-input AND gates
7422 - Two four-input NAND gates with open collector
7423 - Two four-input NOR gates with strobe expandable
7425 - Two four-input NOR gates with strobe
7426 - Four two-input NAND gates with 15V outputs with open collector
7427 - Three NOR gates with three inputs
7428 - Four two-input NOR gates
7430 - An eight input NAND gate
7431 - Six delay elements - of the order of 27.5 ns ( 1.6 ) , 46.5 ns ( 2.5 ) and 6ns ( 3.4 ) .
7432 - Four two-input OR gates
7433 - Four NOR buffer gates with two inputs open collector
7436 - Four two-input NOR gates ( different pinout 7402 )
7437 - Four two-input NAND gates
7438 - Four two-input NAND gates with open collector
7439 - Four NAND buffer of two inputs
7440 - Two NAND buffer with four entries
7441 - Driver BCD to Decimal Decoder / Nixie valve (obsolete )
7442 - BCD to Decimal Decoder
7443 - Decoder Excess - 3 to Decimal
7444 - Decoder Gray- Excess - 3 to Decimal
7445 - BCD to Decimal Decoder
7446 - BCD to 7-segment decoder outputs with 30V open collector
7447 - BCD to 7-segment decoder outputs with 15V open collector
7448 - BCD to 7 segment decoder with stopping
7449 - BCD to 7 segment decoder with open collector
7450 - Two gates AND-OR -AND 2 -wide two inputs (one gate expandable )
7451 - Two gates AND-OR -AND 2 -wide two-input
7452 - AND-OR 4 - Door Wide two expandable entries
7453 - AND-OR -NOT gate 4 - Wide two expandable entries
7454 - AND-OR -NOT gate 4 -wide two-input
7455 - AND-OR -NOT Gate 2 Wide - four entries ( 74H version is expandable )
7460 - Two expanders four entries
7461 - Three expanders three entries
7462 - expanders 3-2- 2-3- entries
7463 - Six interface ports sensitive current
7464 - AND-OR -NOT 4-2 3- port 2- input
7465 - AND-OR -NOT gate with open collector inputs 4-2-3-2
7470 - JK Flip Flop with Preset and Clear with AND gate activated by the rising edge
74H71 - JK Flip -Flop with Preset master slave with AND - OR gate
74L71 - RS Flip -flop master slave with Preset and Clear with AND gate
7472 - Flip - Flop JK master slave with Preset and Clear with AND gate
7473 - Two Flip - Flops with Clear JK
7474 - Two Flip - Flops type D with Preset and Clear assets by rising edge
7475 - Bistable Latch 4-bit

7476 - Dois JK flip- flops com Preset and Clear
7477 - Latch biestável two 4 - bits
74H78 , 74L78 - Dois JK flip - flops com Preset , Clear and Clock comum comum
74LS78A - Dois JK flip - flops com Preset , Clear and Clock comum comum ativos in borda two descida
7479 - Dois D flip- flops
7480 - Somador completo com disparo
7481 - 16 bits of RAM Random Access Memory MEMORIA
7482 - c completo de 2 bits
7483 - Somador completo of 4 bits
7484 - MEMORIA RAM of 16 bits
7485 - Comparador of magnitude of 4 bits
7486 - Quatro will XOR (you exclusivo ) de duas entradas
7487 - Elemento Verdadeiro / Complemento / Zero / Um de quatro bits
7488 - 256 bits of ROM MEMORIA
7489 - MEMORIA two leitura / escrita of 64 bits
7490 - Contador de década ( seções divide and divide in 2 in 5 separadas )
7491 - Registrador two deslocamento com entrada de 8 bits Serial , Serial and saída entradas com disparo
7492 - Contador divisor in 12 ( seções divide and divide in 2 in 6 separadas )
7493 - Contador binário of 4 bits ( seções divide in 2 and divide in 8 separadas )
7494 - Registrador two deslocamento of 4 bits , dois Presets assíncronos
7495 - Registrador two deslocamento of 4 bits , entrada paralela , saída paralela , bidirecional
7496 - Registrador two deslocamento com entrada paralela , saída paralela and Preset assíncrono
7497 - Multiplicador binário síncrono of 6 bits
7498 - Registrador two armazenamento / seleção two dados of 4 bits
7499 - Registrador two deslocamento of 4 bits bidirecional Universal
74100 - Dois latch biestáveis ​​of 4 bits
74101 - Flip - Flop JK ativo in borda two descida com Preset and com disparo in PORTA AND - OR
74102 - Flip - Flop JK ativo in borda two descida com Preset and Clear com disparo in PORTA AND
74103 - Dois JK flip - flops in ativos borda two descida com Clear
74104 - Flip - Flop JK Mestre Escravo
74105 - Flip - Flop JK Mestre Escravo
74106 - Dois JK flip - flops in ativos borda two descida com Preset and Clear
74107 - Dois JK flip - flops com Clear
74107A - Dois JK flip - flops in ativos borda two descida com Clear
Oklahoma, 74108 - Fois JK flip- flops in ativos borda two descida com Preset , Clear and Clock comum comum
74109 - 8Dois flip - flops - J - K Note ativos in borda two subida com Preset and Clear
74110 - Flip - Flop JK Mestre Escravo com disparo in PORTA AND routinely de dados com
74111 - Dois JK flip - flops Mestre Escravo com routinely de dados
74112 - Dois JK flip - flops in ativos borda two descida com Clear and Preset
74113 - Dois JK flip - flops in ativos borda two descida com Preset
Oklahoma, 74114 - Dois JK flip - flops in ativos borda two descida com Preset , Clear and Clock comum
74116 - Dois de Lachaise 4 bits com Clear
74118 - possible service Lachaise set / reset
74119 - possible service Lachaise set / reset
74120 - Dois Excitadores / Sincronizadores of pulso
74121 - Multivibrador monoestável
74122 - Multivibrador monoestável reativável com Clear
74123 - Dois multivibradores monoestáveis ​​reativáveis ​​com Clear
74124 - Dois osciladores controlados in tensão
74125 - Quatro com saídas tristate buffers , ativos in sinal negativo
Oklahoma, 74126 - Quatro com saída tristate buffers , ativos in sinal positivo
74128 - Quatro de duas will NOR entradas esxitadores two linha
74130 - Quatro will AND entrada de duas buffers com saídas two 30V com coletor aberto

74131 - Four ports AND bubbers entry with two 15V outputs with open collector
74132 - Four two-input NAND gates with Schmitt Trigger
74133 - Gate NAND thirteen entries
74134 - Gate NAND twelve inputs with tristate output
74135 - Four ports NOR / XOR of two inputs
74136 - Four ports XOR ( exclusive or) two entrances with open collector
74137 - Decoder / Demultiplexer 3 to 8 lines with Address Latch
74138 - Decoder / Demultiplexer 3 to 8 lines
74139 - Two Decoders / Demultiplexers 2 to 4 lines
74140 - Two four-input NAND gates with line driver
74141 - Decoder / Driver BCD to Decimal
74142 - decade counter / 4 bit Latch / Decoder to 7-segment 4 -bit / Driver
74143 - decade counter / latch / decoder / exctador with constant current of 15 mA
74144 - decade counter / latch / decoder / driver with 15V output with open collector
74145 - BCD to Decimal Decoder / Driver
74147 - Priority Encoder 10 lines to 4 lines
74148 - Encoder Priority 8 lines to 4 lines
74150 - Data Selector / Multiplexer 16 lines to 1 line
74151 - Data Selector / Multiplexer 8 lines to 1 line
74152 - Data Selector / Multiplexer 8 lines to 1 line
74153 - Two Data Selectors / Multiplexers lines 1 to 4 lines
74154 - Demultiplexer 4 lines to 16 lines
74155 - Two demultiplexers 2 lines to four lines
74156 - Two demultiplexers 2 lines to four lines with open collector
74157 - Two multiplexers / selectors data from 2 lines to 1 line without inverting output
74158 - Two data selectors / multiplexers 2 lines to 1 line with inversion output
74159 - Demultiplexer 4 lines to 16 lines with open collector
74160 - synchronous decade counter with 4-bit asynchronous Clear
74161 - Counter Synchronous 4 -bit Binary with Asynchronous Clear
74162 - synchronous decade counter with synchronous 4-bit Clear
74163 - 4 -bit binary counter with synchronous clear
74164 - Recorder displacement serial 8 -bit parallel output with asynchronous clear
74165 - Recorder displacement serial 8 -bit parallel loads and complemented outputs
74166 - Recorder 8-bit shift
74167 - Multiplier rate synchronous decade
74168 - decade counter / 4 bit synchronous descending ascending
74169 - [ [ Counter / Synchronous Down 4 -bit Binary Up
74170 - Stock 4 by 4 registrars with open collector outputs
74172 - Bank registers with carry multiple 16-bit tristate outputs
74173 - Four D flip-flops with tristate outputs
74174 - Six D flip-flops with common clear
74175 - Four D flip-flops for active edge with complementary outputs and asynchronous clear
74176 - decade counter / pre - Adjustable Latch
74177 - decade counter / pre - Adjustable Latch
74178 - Recorder displacement 4 -bit parallel access
74179 - Recorder displacement 4 -bit parallel access , asynchronous clear and complementary outputs
74180 - Generator and Checker Parity Even / Odd 9 bits
74181 - arithmetic logic unit and function generator 4-bit
74182 - Generator carry future
74183 - Full Adder with two carry -save
74184 - Decoder BCD to binary
74185 - Decode binary to BCD
74186 - Memory ROM 512 bits ( 64 × 8 ) with open collector
74187 - ROM Memory 1024 bits ( 256 × 4 ) open collector
74188 - Memory PROM 256-bit ( 32 × 8 ) with open collector
74189 - RAM 64-bit ( 16 × 4 ) with tristate inverting outputs
74190 - counter decade up / down synchronous
74191 - counter binary up / down synchronous
74192 - Counter decade ascending / descending with synchronous clear
74193 - 4 -bit binary counter ( modulo 16 ) ascending / descending
74194 - Recorder displacement of 4 -bit bidirectional universal
74195 - Recorder displacement 4 -bit parallel access
74196 - Latch / Counter decade presettable
74197 - Latch / presettable binary counter
74198 - Shift Register 8 -bit bidirectional universal
74199 - Shift Register 8 -bit universal bidirectional with J -Not- K entries
74200 - RAM 256 -bit tristate outputs
74201 - RAM 256 bits ( 256 × 1 ) with tristate outputs
74206 - RAM 256-bit open collector
74209 - 1024-bit RAM (1024 × 1 ) with tristate outputs
74210 - Eight buffers
74219 - RAM 64-bit ( 16 × 4 ) with tristate outputs nãoinversoras
74221 - Two monostable multivibrators with Schmitt trigger inputs
74224 - FIFO memory 16 by 4 Synchronous with tristate outputs
74225 - FIFO Memory 16 × 5 asynchronous
74226 - Transceiver 4 -bit parallel data outputs to tristate
74232 - Four Door NOR Schmitt trigger
74237 - Decoder / Demultiplexer 1 to 8 with address latches and outputs active at high level
74238 - Decoder / Demultiplexer 1 to 8 with active outputs at high level
74239 - Two Decoders / Demultiplexers 2 for 4 with active outputs at high level
74240 - Eight inverting buffers with tristate outputs
74241 - Eight buffers with non- inverting outputs tristade
74242 - Four transceivers with data tristate inverting outputs
74243 - Four transceivers with data tristate non- inverting outputs
74244 - Eight buffers with tristate non- inverting outputs
74245 - Eight transceivers with data tristate non- inverting outputs
74246 - Decoder BCD to 7 segments / Driver with 30V outputs with open collector
74247 - Decoder BCD to 7 segments / Driver with 15V output with open collector
74248 - Decoder BCD to 7 segments / driver outputs with internal pull-up
74249 - Decoder BCD to 7 segments / Driver with open collector
74251 - Data Selector / Multiplexer 8 lines to 1 line with tristate outputs
74253 - Two data selectors / multiplexers 4 lines to 1 line with tristate outputs
74255 - Two Latches 4-bit addressable
74256 - Two Latches 4-bit addressable
74257 - Four data selectors / multiplexers 2 lines to 1 line with tristate non- inverting outputs
74258 - Four data selectors / multiplexers 2 lines to 1 line with tristate inverting outputs
74259 - 8-Bit Addressable Latch
74260 - Two Door NOR of 5 entries
74261 - Parallel Binary Multiplier for 2 bits by 4 bits
74265 - Four elements of complementary output
74266 - Four two-input XNOR gates with open collector
74270 - Memory 2048-bit ROM ( 4 × 512 ) with open collector
74271 - ROM Memory 2048 bits ( 256 × 8 ) with open collector
74273 - 8-bit register with reset
74274 - 4-bit binary multiplier by 4 bits
74275 - Slice 7-bit Wallace Tree
74276 - Four flip- flops J -Not- K for active edge with separate clocks , common preset and clear
74278 - resgisters priority 4 bits cascate [ ables with data entries with latches
74279 - Four set- reset latches
74280 - Checker / Generator Parity Even / Odd 9 bits
74281 - Accumulator 4-bit parallel binary
74283 - Full Adder 4-bit binary
74284 - parallel binary multiplier 4 bit by bit 4 ( 4 low-order bits of the product )
74285 - parallel binary multiplier 4 bit by bit 4 ( 4 high-order bits of the product )
74287 - Memory PROM 1024 bits ( 256 × 4 ) with tristate outputs
74288 - Memory PROM 256-bit ( 32 × 8 ) with tristate outputs
74289 - RAM 64 - bit ( 16 × 4 ) open collector
74290 - Counter decade ( sections divided by 2 and divide by 5 separate
74291 - Recorder displacement of 4 -bit universal counter binary up / down synchronous
74292 - Digital timer / programmable frequency divider
74293 - 4 -bit binary counter ( sections divided by 2 and divide by 8 separate
74294 - Digital timer / programmable frequency divider
74295 - 4-bit bidirectional Recorder with tristate outputs
74297 - Digital Filter Phase-Locked - Loop
74298 - Four 2-input multiplexer with storage
74299 - Recorders shift / storage of 8 -bit universal bidirectional with tristate outputs
74301 - RAM 256 bits ( 256 × 1 ) with open collector
74309 - 1024-bit RAM (1024 × 1 ) with open collector
74310 - Eight buffers with Schmitt trigger inputs
74314 - 1024-bit RAM
74322 - Recorder 8-bit shift with sign extension and tristate outputs
74323 - Recorder shift / storage of 8 -bit tristate outputs
74324 - Voltage controlled oscillator (or crystal-controlled )
74340 - Eight buffers with Schmitt trigger inputs and outputs tristate inverter
74341 - Eight buffers with Schmitt trigger inputs and outputs tristate non- inverting
74344 - Eight buffers with Schmitt trigger inputs and outputs tristate non- inverting
74348 - Encoder priority for 3 lines of 8 lines with tristate outputs
74350 - 4- Bit Shifter with tristate outputs
74351 - Two multiplexers / selectors 8 data lines to 1 line with tristate outputs and 4 inputs common data
74352 - Two multiplexers / selectors 4 data lines to 1 line with inverting outputs
74353 - Two multiplexers / selectors 4 data lines to 1 line with tristate outputs
74354 - Multiplexer / Selector 8 data lines to 1 line transparent latch with tristate outputs and
74356 - Multiplexer / Selector 8 data lines to 1 line with recording enabled by edge and tristate outputs
74362 - Excidador / Clock Generator phase (also known as TIM9904 )
74365 - Six buffers with tristate non- inverting outputs
74366 - Six inverting buffers with tristate outputs
74367 - Six buffers with tristate non- inverting outputs
74368 - Six inverting buffers with tristate outputs
74370 - ROM Memory 2048 bits (512 × 4 ) with tristate outputs
74371 - ROM Memory 2048 bits ( 256 × 8 ) with tristate outputs
74373 - Eight transparent latches with tristate outputs
74374 - Eight registrars with tristate outputs
74375 - Four bistable lacthes
74376 - Four flip- flops J -Not- K with common clock and common clear
74377 - Recorder 8-bit with Clock Enable
74378 - Recorder 6 bits with Clock Enable
74379 - 4-bit Register with Clock Enable and complementary outputs
74380 - Recorder 8-bit multifunction
74381 - Arithmetic Logic Unit / Function Generator with 4-bit outputs of generation and propagation
74382 - Arithmetic Logic Unit / Function Generator with 4-bit outputs Ripple Carry and Overflow
74385 - Table adders / subtractors of 4 bits
74386 - Four 2-input XOR gates
74387 - Memory PROM 1024 bits ( 256 × 4 ) open collector
74390 - Two decade counters 4-bit
74393 - Two 4 -bit binary counters
74395 - Recorder universal shift 4 bits with tristate outputs
74398 - Four 2-input multiplexer with storage and complementary outputs
74399 - Four 2-input multiplexer with storage
74408 - Tree 8 parity bits
74412 - Latch 8-bit multi - buffered mode with tristate outputs and clear ( the 74S412 is equivalent to the Intel 8212 , TI TIM8212 )
74423 - Two monostable multivibrators reativáveis
74424 - Driver / Clock generator phase ( 74LS424 is equivalent to the Intel 8224 , TI TIM8224 )
74425 - Four doors with tristate outputs and assets Enables low-level
74426 - Four doors with tristate outputs and Enables active at high level
74428 - Controller 8080A system for ( 74S428 is equivalent to the Intel 8228 , TI TIM8228 )
74438 - Controller 8080A system for ( 74S438 is equivalent to the Intel 8238 , TI TIM8238 )
74440 - Four three-way data transceivers with open collector outputs with non- inverting
74441 - Four three-way data transceivers with open collector inverter outputs
74442 - Four transceivers of three-way data with non- inverting tristate outputs
74443 - Four transceivers of three-way data with tristate inverting outputs
74444 - Four transceivers of three-way data with inverting and non- inverting outputs
74448 - Four transceivers of three-way data with inverting and non- inverting outputs with open collector
74450 - Multiplexer 16 lines to 1 line with complementary outputs
74451 - Two multiplexers 8 lines to 1 line
74452 - Two synchronous decade counters
74453 - Two synchronous binary counters
74453 - Multiplexer 4 lines to 1 line
74454 - Two decade counters ascending / descending with synchronous preset input
74455 - Two binary counters ascendentess / synchronous offspring with preset input
74456 - Adder NBCD ( Natural Binary Coded Decimal )
74460 - Switch for data transfer
74461 - 8 -bit binary counter presettable with tristate outputs
74462 - transmitter fiber optic link
74463 - Receiver fiber optic link
74465 - Eight buffers with tristate outputs
74468 - Two converters MOS level TTL
74470 - Memory PROM 2048 bits ( 256 × 8 ) with open collector
74471 - Memory PROM 2048 bits ( 256 × 8 ) with tristate outputs
74472 - PROM memory with open collector
74473 - Memory PROM with tristate outputs
74474 - PROM memory with open collector
74475 - Memory PROM with tristate outputs
74481 - Elements of 4 -bit slice processing
74482 - Elements of 4 -bit slice scalable processing
74484 - Decoder BCD to binary ( SN74S371 masked programmed ROM )
74485 - Decode binary to BCD ( SN74S371 masked programmed ROM )
74490 - Two decade counters
74491 - Counter 10 ascending / descending bit binary on a preset and tristate outputs
74498 - Shift Register 8 -bit bidirectional parallel outputs and tristate outputs
74508 - Multiplier / Divider 8 bits
74521 - Compare 8 -bit
74531 - Eight transparent latches with tristate outputs 32 mA
74532 - Eight registrars with tristete 32 mA outputs
74533 - Eight transparent latches with tristate inverting outputs
74534 - Eight registrars with tristate inverting outputs
74535 - Eight transparent latches with tristate inverting outputs
74536 - Eight registrars with tristate inverting outputs of 32 mA
74537 - BCD to decimal decoder with tristate outputs
74538 - De multiplexers 1 line to 8 lines with tristate outputs
74539 - Two de multiplexers 1 line to 4 lines with tristate outputs
74540 - Eight buffers with tristate outputs
74541 - Eight buffers with tristate outputs
74560 - decade counter with 4-bit tristate outputs
74561 - 4 -bit binary counter with tristate outputs
74563 - Transparent Latch 8-bit D-type inverter with tristate output
74564 - Recorder 8-bit D-type activated edge with tristate outputs
74568 - Counter decade ascending / descending with tristate outputs
74569 - counter binary up / down with tristate outputs
74573 - Eight D-type transparent latches with outputs trsitate
74574 - Eight flip- flops of type D with tristate outputs
74575 - Eight flip -flops with synchronous type of clear and tristate outputs
74576 - Eight flip- flops D-type inverter with tristate outputs
74577 - Eight flip- flops of type D with synchronous clear and inverting tristate outputs
74580 - Eight transceivers / latches with tristate inverting outputs
74589 - Recorder 8-bit shift latch with input and tristate outputs
74590 - 8 -bit binary counter with output registers and tristate outputs
74592 - 8 -bit binary counter with output register
74593 - 8 -bit binary counter with input registers and tristate outputs
74594 - with serial shift register with input latches output
74595 - Logger with serial input shift registers with output
74596 - Recorder shift registers with serial input with open collector output and
74597 - serial shift register with output latches input
74598 - Shift Register with Input Latches
74600 - Controller dynamic memory refresh , transparende modes and burst (burst ) for DRAMs 4 KB or 16 KB ( 74LS600 is equivalent to TI TIM99600 )
74601 - Controller dynamic memory refresh , transparende modes and burst (burst ) , 64 KB for DRAMs ( 74LS601 is equivalent to TI TIM99601 )
74602 - Controller dynamic memory refresh , cycle ways and Rejada fast (burst ) for DRAMs 4 KB or 16 KB ( 74LS602 is equivalent to TI TIM99602 )
74603 - Controller dynamic memory refresh , cycle ways and Rejada fast (burst ) , 64 KB for DRAMs ( 74LS603 is equivalent to TI TIM99603 )
74604 - Eight 2-input multiplexers with lacthes high-speed tristate outputs ( 74LS604 is equivalent to TI TIM99604 )
74605 - Eight 2-input multiplexers with lacthes high speed open collector ( 74LS605 is equivalent to TI TIM99605 )
74606 - Eight 2-input multiplexers with lacthes free of glitches with tristate outputs ( 74LS606 is equivalent to TI TIM99606 )
74607 - Eight 2-input multiplexers with lacthes , fault free , open collector ( 74LS607 is equivalent to TI TIM99607 )
74608 - Controller memory cycle ( 74LS608 is equivalent to TI TIM99608 )
74610 - Memory Mapper with latches and tristate outputs ( 74LS610 is equivalent to TI TIM99610 )
74611 - Memory Mapper with latches and open collector ( 74LS611 is equivalent to TI TIM99611 )
74612 - Memory Mapper with tristate outputs ( 74LS612 is equivalent to TI TIM99612 )
74613 - Mapper memory with open collector ( 74LS613 is equivalent to TI TIM99613 )
74620 - Eight transceivers with data tristate inverting outputs
74621 - Eight transceivers for data with non- inverting outputs , open collector
74622 - Eight data transceivers with open collector outputs and inverting
74623 - Eight transceivers with data tristate non- inverting outputs
74624 - Voltage controlled oscillator with activation control , range control and outputs biphasic
74625 - Two voltage controlled oscillators with biphasic outputs
74626 - Two voltage-controlled oscillators with controlled activation and outputs biphasic
74627 - two voltage controlled oscillators
74628 - Voltage controlled oscillator with activation control , range control , external temperature compensation and outputs biphasic
74629 - Two controlled by voltage -controlled activation and control oscillators track
74630 - Detector and error correction ( EDAC ) 16-bit tristate outputs
74631 - Detector and error correction ( EDAC ) 16-bit open collector
74632 - Detector and error correction ( EDAC ) 32-bit
74638 - Eight transceivers with data tristate inverting outputs
74639 - Eight transceivers with data tristate non- inverting outputs
74640 - Eight transceivers with data tristate inverting outputs
74641 - Eight transceivers for data with non- inverting outputs , open collector
74642 - Eight data transceivers with open collector outputs and inverting
74643 - Eight data transceivers with tristate outputs inverting and non- inverting
74644 - Eight data transceivers with inverting and non- inverting outputs , open collector
74645 - Eight transceivers data
74646 - Eight transceivers data / Latches / Multiplexers with tristate outputs
74647 - Eight transceivers data / Latches / Multiplexers with open collector
74648 - Eight transceivers data / Latches / Multiplexers with Inverting tristate outputs
74649 - Eight transceivers data / Latches / multiplexers with inverting open collector outputs and
74651 - Eight transceivers / Data Logger with tristete inverting outputs
74652 - Eight transceivers / Data Logger with tristate non- inverting outputs
74653 - Eight transceivers / Data Logger with tristate inverters and open collector outputs
74654 - Eight transceivers / Data Logger with tristate non- inverting outputs , open collector
74658 - Eight data transceivers with parity , inverters
74659 - Eight data transceivers with parity , non- inverters
74664 - Eight data transceivers with parity , inverters
74665 - Eight data transceivers with parity , non- inverters
74668 - Counter decade of synchronous 4 -bit up / down
74669 - Counter Synchronous 4 -bit up / down binary
74670 - Bank registers 4 for 4 with tristate outputs
74671 - Registradore displacement 4-bit bidirectional / Multiplexer with tristate outputs
74672 - Registradore displacement 4-bit bidirectional / Latch / Multiplexer with tristate outputs
74673 - Shift Register 16-bit serial input and serial output with output storage registers and tristate outputs
74674 - Shift Register 16-bit parallel input and serial output with tristate outputs
74677 - Compare 16-bit address to enable
74678 - Compare 16-bit address latch with
74679 - Compare 12 -bit address latch
74680 - Compare address with 12 bits enable
74681 - Accumulator 4-bit parallel binary
74682 - Compare magnitude of 8 bits
74683 - Compare magnitude 8-bit open collector
74684 - Compare magnitude of 8 bits
74685 - Compare magnitude 8-bit open collector
74686 - Compare magnitude of 8 bits to enable
74687 - Compare magnitude of 8 bits to enable
74688 - Compare magnitude of 8 bits
74689 - Compare magnitude 8-bit open collector
74690 - 4 -bit decimal counter / latch / multiplexer with asynchronous reset and tristate outputs
74691 - 4-bit Counter / Latch / Multiplexer binary with asynchronous reset and tristate outputs
74692 - 4 -bit decimal counter / latch / multiplexer with synchronous reset and tristate outputs
74693 - 4-bit Counter / Latch / Multiplexer with binary synchronous reset and tristate outputs
74694 - 4-bit Decimal Counter / Latch / Multiplexer with synchronous and asynchronous resets and tristate outputs
74695 - 4-bit Counter / Latch / Multiplexer with binary synchronous and asynchronous resets and tristate outputs
74696 - 4-bit Decimal Counter / Register / Multiplexer with asynchronous reset and tristate outputs
74697 - 4-bit Counter / Register / Multiplexer binary with asynchronous reset and tristate outputs
74698 - 4-bit Decimal Counter / Register / Multiplexer with synchronous reset and tristate outputs
74699 - 4-bit Counter / Register / Multiplexer with binary synchronous reset and tristate outputs
74716 - programmable decade counter ( 74LS716 is equivalent to Motorola MC4016 )
74718 - Programmable Binary Counter ( 74LS718 is equivalent to MC4018 )
74724 - Multivibrator Voltage controlled
74740 - Eight buffers / drivers inverter line with tristate outputs
74741 - Eight buffers / line drivers of non- tristate inverters with outputs and polarity enable mixed
74744 - Eight buffers / line drivers of non- tristate inverters with outputs
74748 - priority encoder 8 to 3 lines
74783 - Synchronous Address Multiplexer ( 74LS783 is equivalent to Motorola MC6883 )
74790 - Detector and error corrector ( EDAC )
74795 - Eight buffers with tristate outputs ( 74LS795 is equivalent to 81LS95 )
74796 - Eight buffers with tristate outputs ( 74LS796 is equivalent to 81LS96 )
74797 - Eight buffers with tristate outputs ( 74LS797 is equivalent to 81LS97 )
74798 - Eight buffers with tristate outputs ( 74LS798 is equivalent to 81LS98 )
74804 - Six NAND gates two drivers entries
74805 - Six NOR gates two excitatory inputs
74808 - Six ports AND two excitatory inputs
74832 - Six ports OR two excitatory inputs
74848 - priority encoder 8 to 3 lines with tristate outputs
74873 - Eight transparent latches
74874 - Eight flip- flops of type D
74876 - Eight flip- flops of type D
74878 - Two flip- flops dp D-type 4 -bit synchronous clear and non- inverting tristate outputs
74879 - Two flip- flops dp D-type 4 -bit synchronous clear and inverting tristate outputs
74880 - Eight transparent latches with inverting outputs
74881 - Arithmetic Logic Unit / Function Generator 4 bits
74882 - Generator carry future 32-bit
742 960 - Detector and error corrector ( EDAC ) ( 74F2960 is equivalent to AMD Am2960 )
742 961 - Buffer inverter EDAC data
742 962 - Buffer EDAC data noninverting
742 968 - Dynamic Memory Controller
742 969 - Controller sync memory for use with EDAC
742 970 - Controller sync memory for use without EDAC
744 060 - ripple counter with oscillator 14-stage
744 538 - Two monostable multivibrators Precision - adjustable and redisplayed
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