Breadboard Sockets

In order to temporarily construct a circuit without damaging the components used to build it, we must have some sort of a platform that will both hold the components in place and provide the needed electrical connections. In the early days of electronics, most experimenters were amateur radio operators. They constructed their radio circuits on wooden breadboards, which allowed them room to mount such things as vacuum tube sockets and larger, heavy components with sufficient room between them, and to connect components from pin to pin of the different sockets in order to complete the circuit.

Although more sophisticated techniques and devices have been developed to make the assembly and testing of electronic circuits easier, the concept of the breadboard remains, and the process of assembling components on a temporary platform is still known as "breadboarding."

---

The figure to the right shows a small, modern breadboarding socket. The socket itself is molded nylon; the actual device is 3½" long and just about an inch and 3/8 wide. Along the center a groove is molded in, except for small sections in the middle and at either end, to maintain strength and stability. Above the groove you see a series of columns of five holes each, with a matching set of columns below the groove.

The holes on each side of the central groove are all spaced 0.1" apart; the groove separates the two sets of holes by 0.3". This makes this type of breadboard socket ideal for mounting integrated circuits (ICs) of the dual-in-line type.

The important factor here is that the five holes in each individual column are electrically connected to each other, but remain insulated from all other sets of holes. This is accomplished as shown to the right. This is an underside view of the breadboard socket with the insulating layer of paper removed. The nylon block contains a series of rectangular slots with thin walls between the slots. A prefabricated set of contacts, similar to the detail shown here, is inserted into each slot to provide the required electrical connections as well as to hold each component lead securely.

---

This breadboard socket is useful and works well for experiments of many kinds. However, it is limited is size and capability. A larger version is shown below:

This larger socket is 6½" long and 3¼" wide. The middle area works just like a longer version of the smaller breadboard socket you saw first on this page: each column of five holes is electrically connected, but is also insulated from all other parts of the breadboard.

Beyond the main columns of holes, however, you'll note four sets or groups of holes along the top and bottom. Each of these consists of five separate sets of five holes each, for a total of 25 holes. These groups of 25 holes are all connected together. This makes them ideal for distributing power to multiple ICs or other circuits.

There are a number of variations on this breadboard socket arrangement, but they all serve the same functions of allowing individual components and ICs to be mounted on a stable platform, and then facilitating the interconnection of these components to form an electronic circuit that can be observed and tested while in operation.

---

These breadboarding sockets are sturdy and rugged, and can take quite a bit of handling. However, there are a few rules you need to observe, in order to extend the useful life of the electrical contacts and to avoid damage to components. These rules are:

• Always make sure power is disconnected when constructing or modifying your experimental circuit. It is possible to damage components or incur an electrical shock if you leave power connected when making changes.
• Never use wire larger than AWG #22 solid hookup wire as jumpers. #24 wire (used for normal telephone wiring) is an excellent choice for this application. Observe the same limitation with respect to the size of component leads.
• Whenever possible, use ¼ watt resistors in your circuits. ½ watt resistors may be used when necessary; resistors of higher power ratings should never be inserted directly into a breadboard socket.
• Never force component leads into contact holes on the breadboard socket. Doing so can damage the contact and make it useless. You may find it helpful to use diagonal cutters to cut off the very end of a component lead. This will leave a wedge-shaped end on a component lead, to make for easier insertion.
• Do not insert stranded wire or soldered wire into the breadboard socket. If you must have stranded wire (as with an inductor or transformer lead), solder (or use a wire nut to connect) the stranded wire to a short length of solid hookup wire, and insert only the solid wire into the breadboard.

If you follow these basic rules, your breadboarding system will last indefinitely, and your experimental components will last a long time.

source

MRF317 FM Amplifier Circuit for 88-108 MHz FM amplifier is used for amplify signal from exciter in broadcast radio station. In this page, RF FM Ampli

MRF317 FM Amplifier Circuit for 88-108 MHz

FM amplifier is used for amplify signal from exciter in broadcast radio station. In this page, RF FM Amplifier uses solid state material with minimum gain 9dB. Input FM Amplifier needs 5-10 watt with power output about 100 watt.

The Block schematic and datasheet

40W Broadband FM RF Power Amplifier [40W MRF171A VHF RF Amplifier for FM Broadcast] Here's broadband RF power amplifier for FM amplifier design is ba

40W Broadband FM RF Power Amplifier

Here's broadband RF power amplifier for FM amplifier design is based on Motorola MRF171A MOSFET. The amplifier was constructed in a small aluminium diecast box. RF input from transmitter and output connections are made by coaxial sockets. The power supply is routed through a ceramic feedthrough capacitor bolted in the wall of the box.

This constructional techniques results in excellent shielding, preventing RF radiation escaping from the amplifier. Without it, significant amounts of RF radiation could be radiated, interfering with other sensitive circuits such as VCOs and audio stages, also significant amounts of harmonic radiation could occur.

Any RF power amplifier must be followed by a low pass filter (LPF) to reduce the harmonics to an acceptable level. What this level is in a unlicensed application is a moot point, but as the output power is increased, more attention must be be paid to the harmonic suppression.

In this RF power amplifier design used a 7 pole Chebyshev low pass filter. A Chebyshev was chosen as the phase and amplitude ripple within the passband was not critical, and the Chebyshev gives a better stop band attenuation than compared to say, a Butterworth. The design stopband was chosen to 113MHz, giving a 5MHz implementation margin from the highest desired passband frequency at 108MHz and the start of the stopband at 113MHz.

The next critical design parameter was the passband ripple. For a single frequency design it is normal practice to choose a large passband ripple, for example 1dB, and tune the peak of the last passband maxima to the desired output frequency. This gives the best stopband attenuation because greater passband ripple results in more rapid stopband attenuation. A seven pole filter has 7 reactive elements, in this design four capacitors and three inductors. The more poles, the better the stopband attenuation, at the expense of increased complexity and more passband insertion loss. An odd number of poles is required as both the input and output impedance was designed to be 50R.


40W Broadband FM RF Power Amplifier

1.5Watt/ 7Watt power adjustment FM Transmitter

Package included:

• 1.5Watt/ 7Watt PLL FM Radio Stereo Broadcast Transmitter With LCD X1
• 3.5mm stereo audio interlink cable X1
• Common GP antanna X1
• Power supply X1

Detail:

Download User's Guide

Specification:

Frequency range: 87MHz ~ 108 MHz

Tuning Step: 100kHz /1Mhz

Transmit Power: 1.5Watt/ 7Watts

Stability of Frequency: ±0ppm（-10℃~+50℃）

Ripple or harmonic waves: <= -60dB

Modulate Frequency error:<=75KHz（100%）

Freq. Response: 100~15000Hz

Antenna Connector: BNC type

Output Impedance: 50 ohm

Audio Input Connector: 3.5mm headphone connector

MIC Input Connector: 3.5mm headphone connector

Power Supply: 12V DC (The current load of power supply should over 2A)

If you can match a good antenna to the FM transmitter, the effect will be better.The transmission range depends on many factors. The true distance is based on the sensitivity of the receiver, antenna of the receiver, and the building and other obstructions, which are between the transmitter and receiver. And the distance will much more in countryside.

ATTENTION: Never power on the transmitter when an antenna is not connected!!!

Our products are low-cost, high-quality.

The use of our products is very easy to build mini-FM radio station.

If you are interested this product, please contact us: rechuen@163.com

1.5Watt/ 7Watt PLL FM Radio Stereo Broadcast Transmitter With LCD

Common GP antanna

Power supply

3.5mm stereo audio interlink cable

500mW PLL Home FM Radio Stereo Broadcast Transmitter Pack

This is a very beautiful home transmitters！

This item includes 500mW LCD display FM transmitter, 100-240V AC Adapter, Drawbars antenna, 3.5mm headphone audio line, RCA Jack Adapter

This stereo FM transmitter can easily build a wonderful FM radio station. This one have a beautiful aluminum alloy cover(Color: Gray).

Specification:

　　 1, uses:This product is the factory, OEM, schools, individuals, car FM radio, the ideal district FM radio broadcasting equipment.

　　 2, performance characteristics:

• Complete machine produced using high-quality aluminum alloy, blue backlit LCD display frequency.

• Japan ROHM motherboard for the next-generation integrated NC FM stereo radio chip PLL BH1415F, built-in PLL frequency PLL, audio pre-emphasis, limiter and low pass filter circuit. Make sound more sweet.
• AT89C2051 and the control board by the AT24C02 composition; After the 2sc9018, 2SC3355,2sc2053 and a total of 3 power amplifier output after.
• Overall shielding good, compact structure, small size, appearance generous.

　　 3, main technical parameters:

• Power supply voltage: DC 10-13.8V (12V recommended)
• Current work: <1a
• Frequency range: 88 ~ 108Mhz
• Frequency Step value: 100kHz
• Frequency stabilization way: PLL
• Frequency stability: ± 10 ppm (-10 ° C +60 ° C )
• Frequency Modulation: ≤ ± 75kHz (100%)
• Work methods: continuous work
• Clutter and Harmonic: less than-60dB
• SNR: ≥ 60dB
• Stereo separation:-50dB
• Audio frequency response: 100 to 15000Hz
• Audio distortion: <2%
• Modulation: 15%
• Input Level:-15dBV (adjustable)
• RF output impedance: 50 Ohm
• Antenna Connector: BNC type
• Audio Input Connector: 3.5mm headphone connector
• RF output power: 500mW (near the center frequency of 5MHz)
• Reference range: 200m - 800m (A barrier-free environment )
• Unit dimensions: L 112mm x W 74mm x H 28mm

Tested strictly For FCC Compliant!!!

If you can match a good antenna to the FM transmitter, the effect will be better.The transmission range depends on many factors. The true distance is based on the sensitivity of the receiver, antenna of the receiver, and the building and other obstructions, which are between the transmitter and receiver. And the distance will much more in countryside.

ATTENTION: Never power on the transmitter when an antenna is not connected!!!

500mW FM Transmitter

[not include The Card]

[not include The Bear]

3.5mm headphone audio line

RCA Jack Adapter

100-240V AC Adapter

SHOPPING Now: http://www.elecsky.com

PCI MAX 2006+

DIGITAL RDS STEREO FM TRANSMITTER for your PC

What is PCI MAX 2006?
PCI MAX 2006+ is a computer card that will change the way you listen to your MP3's or other audio via PC. It will effectively change your PC into a stereo FM radio station, it is a small digital FM transmitter in a form of a PCI PC card. You will be able to play your audio files (CD, wav, MP3, real audio etc.) from your PC through radio waves directly to your household radio receiver in the next room, in the living room, across your yard, in whole block of flats....or for the entire village/small city. You need just an ordinary radio receiver to receive your signal. The included software (also available in the support section of this website) lets you set the frequency and the output power. You can either service your living room, garden or an entire community. Get rid of those pesky cables!

Installation manual for the PCI MAX 2006+ is here.
Installation manual for the RDS daughter board is here.
Manual for the normal size LCD module is here.
Manual for the miniature LCD module with LED VU meter is here.

How do I install it?
It can never be easier that this. Install this card into your PC as you would any other PC card. Install software and you're ready to broadcast! Software gives you full control over frequency and power. Additional output power and superior audio quality can be obtained by using external power source.
Coupled with MP3 player and scheduling plugins this becomes a fully automated radio station! Perfect for fully automated guided tours, small scale advertising, wireless link from your PC to your stereo in the living room, wireless headsets for translated/interpreted lectures or even a small community radio station...

You are only limited by your imagination!

What is new since PCI MAX 2005?
PCI MAX 2006+ is a major design upgrade from the PCI MAX 2005. We really took our time with this version. We started by analyzing all reported problems with the previous models and we considered various ideas for improvements submitted over the years by the users. We implemented some major changes plus a number of small, but effective improvements, now ensuring excellent audio quality and great stereo separation. Some of the improvements (not all) are listed below:
- External power supply connector was moved to the back for easy access (for those with noisy PC power supplies or perfectionists trying to get the most out of their PC based FM transmitter system. Using external power supply allows for full output power and better audio quality.
- All boards are prepared for RDS, a daughter board is simply plugged in (this could only be done in our laboratory before). Besides, the mounting of RDS board is now much more elegant.
- Additional RF stage for increased isolation (stability) and more RF power (~350mW & 1W versions available). Low power version will be noticeably stronger than the old 2005 cards.
- A LED diode at the PC backplate for transmitter power indication, it makes it possible to check whether transmitter is ON or OFF (and what the power level is). It is very handy for troubleshooting and looks good, too.
- DC/DC convertor is now synchronized with stereo encoder, which eliminates interference problems.
- Power adjustment circuitry has been redesigned entirely and now performs much better.
- PLL loop filter was redesigned for better audio quality.
- 15KHz low pass filter was added (this was really needed as it sounds much better now).
- Improved PCB layout for improved audio quality (less noise from PC).
- An optional external box will be provided as well as miniature LCD display board with VU meter (2x5LEDs)
- 50KHz PLL steps

This is a more/less complete list, some changes may have been implemented, but were not mentioned here. PCI MAX 2006+ has built-in balanced audio inputs, limiters, precise preemphasis and MPX filter. It can be switched to MONO or STEREO by a simple click of a mouse button. There is a phono audio input at the back of the card, which connects to the sound card via provided jumper cable. If you need to keep the particular output for your speakers, simply use splitter (awailable from radio shack or our website). Audio can also be fed to the card from other audio sources (cd players, mixers etc).

Using PCI MAX 2006+ in stand alone mode, without the PC!
PCI MAX 2006+ can also be used in stand alone mode! A small control unit with LCD display can be connected via flat cable and enables changing of the frequency, power and stereo mode. Power jack for the card is already provided on the board, it requires 12-13.8V DC / 1A (center +). Put it in a box and you've got a stand-alone transmitter with high quality stereo encoder, balanced inputs (only pro units have this), optional RDS (similar to RDS MAX 30+) and excellent sound. Add our 15W booster and you've got a nice 15W transmitter.
Small stylish enclosures with special smaller LCD control units (required due to small size of enclosure) and 2x5LED VU meter are available and can be purchased here as well. A normal size LCD control unit, available at this moment, will not fit inside the small stylish enclosure.

What is this RDS thing?
Check the manual for RDS daughter board (link is above) page for more information. Basically it displays station name and sometimes song name (if supported by transmitter) and similar information on a compatible radio receiver. Very popular in Europe, less so in the US.
To enable RDS functionality you need to purchase and install RDS daughter board. It plugs into a socket on the PCI MAX 2006+ board.

If I use PCI MAX in stand-alone mode without the PC, can I still use PC as audio source?
Of course, just plug one end of the audio cable into your sound card and the other into PCI MAX and you're ready to go!

What kind of accesories are available and what can they be used for!

Accesories for stand-alone operation - normal size LCD module
A small control unit with LCD display can be connected via flat cable and enables changing of the frequency, power and stereo mode in stand-alone mode without a PC. Power jack for the card is already provided on the board so you just need a 12-13.8V DC / 1A (center +) power supply and you're ready to go, no PC required.

Accesories for stand-alone operation - 19" rack for normal size LCD module
A 1H 19-inch rack can be purchased as well and is perfect for the PCI MAX 2006+ and the normal size LCD control unit (holes for the LCD and keys are predrilled). There are even holes for balanced XLR connectors at the back and you can take full advantage of the balanced audio inputs.

Accesories for stand-alone operation - miniature LCD module with LED VU meter
This is a much smaller control unit with LCD display and also contains two rows of LED diodes, which either function as a light show or VU meter (they change depending on sound volume). This unit was developed for a smaller box, which is just big enough for the PCI MAX 2006+ and this display unit. The entire unit is extremely compact and portable and looks great in the dark.

Accesories for stand-alone operation - small enclosure for miniature LCD module
This is a much smaller enclosure, which is just big enough for the PCI MAX 2006+ and this display unit. The entire unit is extremely compact and portable and looks great in the dark with back-lit LCD display and LEDs jumping up and down with the music. Especially cool blue background LCD displays can be ordered as well, but cost a bit more. Starts shipping in a few weeks.

Accesories for stand-alone operation - 15W or 300W amplifier
You can increase power by adding our 15W and 300W amplifier.
15W booster requires minimal drive and will work with any version of PCI MAX.
300W amplifier requires 1W version of PCI MAX.
Please make sure you are operating in accordance with local laws when using such high-power amplifiers.

For stand-alone and PC operation - external power supply
Using external power supply while your PCI MAX is installed inside a PC gives your transmitter a bit more power and also eliminates any remaining noise, generated by the PC's power supply.
In stand-alone operation this is of course a non-optional item as you need to power your unit somehow. Power supply will work anywhere in the world, it looks similar to the laptop power supply. The mains cable that plugs into the unit is not included as it is different in every country. It is a standard PC-type and can be purchased in any PC shop or radio shack and costs about 1 US$.

For stand-alone and PC operation - RDS daughter board
Check this page for more information. Basically it displays station name and sometimes song name (if supported by transmitter) and similar information on a compatible radio receiver. Very popular in Europe, less so in the US.
To enable RDS functionality you need to purchase and install RDS daughter board. It plugs into a socket on the PCI MAX 2006+ board. Starts shipping in a few weeks.

For stand-alone and PC operation - various types of antennas
Antenna makes a huge difference. Various types of antennas are available, you can check them out and purchase here. Here's a fast overwiev:
- PCS0205; This is a directional antenna, it has very high gain, but transmits most of the signal in one direction only.
- COMET; This is a very popular omnidirectional antenna, it has average gain, but transmits in all directions.
- Dipole; Less gain than the type above, omnidirectional, but they can be stacked into 2-bay or 4-bay configurations, which are than better than any other omnidirectional antenna we have. This is the best there is for omnidirectional, if you use 2 or 4 dipoles with 2-way or 4-way harness.
- MLB6600; low end, omnidirectional, small gain, but very popular due to low price and the fact that the coaxial cable is inclulded as well.
- PCS0201 ; this is our new omnidirectional unit, it is somewhere in the middle with performance. The only downside is its low power handling capability, only about 2W maximum.

For stand-alone and PC operation - audio Y splitter/adapter
Are you worried about loosing an output from your sound card which is now used for PCI MAX? You can reclaim it with this splitter which enables you to use your sound card output for your sound card and PCI MAX at the same time. Simple and cheap, but usefull and effective!

HOT TIP:
Save 5-10% off product price by promoting our website. Here's how.

PCI MAX 2006+
Miniature box for PCI MAX and mini LCD display unit 19" rack for PCI MAX and big LCD display unit
Mini LCD display for mini enclosure Big LCD display for 19" rack Included antenna. Use a proper antenna such as COMET for 1W version.	Y splitter Supported by SAM2 and SAM3! RDS plug-in upgrade

Technical specifications:

- Format: PCI card
- S/N: > 70dB
- Channel separation: > 60dB (any audiophile tuner will only do 45-50dB)
- Output power: 0-350mW or 0-1000mW/(15W or 150W with booster)
- This unit is perfect for New Zealand and conforms to their limitations!
- Ideal for guided tours, galleries, museums, MP3 broadcasting...
- Full software control over frequency and mode of operation (Mono or stereo)
- Optional external power supply
- 50 kHz PLL steps 87.5-108 MHz (full coverage)
- Digital stereo encoder on board!
- Precise preemphasis on board!
- DC/DC converter on board for improved Signal/noise ratio!

ONLY WE PRODUCE THIS PRODUCT!

	PCIMAX2006+ (350mW)
	PCIMAX2006+ (1W)
	RDS daughter board
	Big LCD control board (stand alone)
	19-inch rack enclosure (stand alone)
	Miniature black anodized enclosure (stand-alone)
	External mains power supply
	Y audio splitter
	Miniature LCD display with VU meter
	15W booster (15V DC)
	Mains power supply for booster
	300W amp in 2H 19-inch rack

source

Chips directory

Chips in the category 'UNKNOWN'

nr	name	description	manufacturer
	SA...	see NE...
	XScale	Intel's successor of the StrongARM. Intel bought the StrongARM from DEC	Intel
0002	LH0002	Buffer, pinout	National Semiconductor
0033	LH0033	Fast Buffer, pinout	National Semiconductor
0063	LH0063	Ultra fast buffer, pinout	National Semiconductor
0094	LH0094	Multifunction Converter, pinout	National Semiconductor
01	AB01	www.icst.com/pdf/AB01.pdf	ICS*
01	KESTX01	Matching transmitter chip	order from Barend
01	an01	www.icst.com/pdf/an01.pdf	ICS*
011	an011	www.icst.com/pdf/an011.pdf	ICS*
013	STA013	Mpeg 2.5 Layer III audio decoder, pinout	ST
02	CCM02-2NO-2193_20	Contacless Smart Card, pinout	ITT Cannon
02	REF02	5V precision volt. ref*, pinout
02	an02	www.icst.com/pdf/an02.pdf	ICS*
0220	mk0220	www.icst.com/pdf/mk0220.pdf	ICS*
0250	SP0250	Speech Synthesizer, pinout	GI
0256	SP0256	Speech Processor, pinout	General Instrument
02803	ADDC02803SC	28V/66W DC/DC Converter Vin=16-50V, Vo=3.3V@21A with EMI Filter, data	AD
02805	ADDC02805SA	28V/66W DC/DC Converter Vin=16-50V, Vo=5V@20A with EMI Filter, data	AD
02808	ADDC02808PB	28 V, 200 W Pulsed DC/DC Converter with Integral EMI Filter, data	AD
02812	ADDC02812DA	28V/100W DC/DC Converter Vin=16-50V, Vo=±12V@8.3A with EMI Filter, data	AD
02815	ADDC02815DA	28V/100W DC Converter Vin=16-50V, Vo=±15V@6.7A with EMI Filter, data	AD
02828	ADDC02828SA	28V/100W DC/DC Converter Vin=16-50V, Vo=28V@3.6A with EMI Filter, data	AD
03	LC03-6	, pinout
03	an03	www.icst.com/pdf/an03.pdf	ICS*
0324	TBB0324A	quad* PNP opamp*, pinout	Siemens
04	AMP04	Precision single supply INAMP, pinout	AD
04	OP-04	OPAMP*, pinout	AD
04	an04	www.icst.com/pdf/an04.pdf	ICS*
042	TBB042G	SMD version van SO42P	order from Barend
042	TDD042G	SO42 SMT version	order from Barend
05	an05	www.icst.com/pdf/an05.pdf	ICS*
05	man05	www.icst.com/pdf/man05.pdf	ICS*
054	TL054	Operational Amplifier, pinout	TI
06	an06	www.icst.com/pdf/an06.pdf	ICS*
060	B060D	BIFET opamp*, pinout	Former East Germany
060	TL060	JFET opamp*, pinout	generic type
061	B061D	BIFET opamp*, pinout	Former East Germany
061	TL061_14pin	Low power J-FET input OP-AMP, pinout	TI
061	TL061_8pin	JFET opamp*, pinout	generic type
062	B062D	dual* BIFET opamp*, pinout	Former East Germany
062	TL062	dual* JFET opamp*, pinout	generic
0620	DS0620	Unknown	Dallas*
0621	DS0621	Unknown	Dallas*
0621	DS0621sdk	Unknown, PS	Dallas*
0630	DS0630x	Unknown, PS	Dallas*
064	B064D	quad* jfet opamp*, pinout	Former East Germany
064	TL064	quad* JFET opamp*, pinout	generic
066	B066D	adjustable JFET opamp*, pinout	Former East Germany
07	an07	www.icst.com/pdf/an07.pdf	ICS*
070	TL070	JFET opamp*, pinout	generic type
071	TL071	JFET opamp*, pinout	generic type
071	TL071CP	see TLC271
072	TL072	dual* JFET opamp*, lo noise, pinout	generic
072	TL072CP	see TLC272
074	TL074	quad* jfet opamp*, pinout	generic
0747	TBB0747A	shortage protected opamp*, pinout	Siemens
0747	TBC0747	shortage protected opamp*, pinout	Siemens
0748	TBB0748B	opamp*, pinout	Siemens
08	an08	www.icst.com/pdf/an08.pdf	ICS*
080	B080D	adjustable JFET opamp*, pinout	Former East Germany
080	TL080	JFET opamp*, pinout	generic type
0803	ADC0803	CMOS* 8-bit A/D converter, pinout	Philips
081	B081D	JFET opamp*, pinout	Former East Germany
081	TL081	JFET opamp*, pinout	generic type
082	B082D	dual* JFET opamp*, pinout	Former East Germany
082	TL082	dual* JFET opamp*, pinout	generic
083	TL083	dual* adjustable jfet opamp*, pinout	generic
084	B084D	quad* jfet opamp*, pinout	Former East Germany
084	TL084	quad* jfet opamp*, pinout	generic
09	OP-09	OPAMP*, pinout	AD
09	man09	www.icst.com/pdf/man09.pdf	ICS*
090494	ANF090494	Keyboard Mux*, pinout	Intel
1	BS1-IC	Basic Stamp 1 Microcontroller, pinout	Parallax
1	EPC1	Serial EPROM*, pinout	Altera
1	spread1	www.icst.com/pdf/spread1.pdf	ICS*
10	KMZ10A	Magnetic field sensor, pinout	Philips
10	KMZ10B	Magnetic field sensor, pinout	Philips
10	KMZ10C	Magnetic field sensor, pinout	Philips
10	LM10	opamp* and voltage ref*, pinout
10	LM10CLWM	opamp* and voltage reference, pinout
10	LM10CWM	opamp* and voltage reference, pinout
10	an10	www.icst.com/pdf/an10.pdf	ICS*
1000	ALD1000	Precision Programmable Current/Voltage Transmitter, pinout	Burr-Brown
1000	X1000	micro-processor, pinout	Globotech
10010	10G010	2:1 MUXed Fanout Buffer, pinout	GigaBit Logic
10016	MC10H016	4-BIT BINARY COUNTER, pinout	Motorola
100171	100171	triple* bit 4-way multiplexer CERDIP24	Philips
100175	100175	5-bit 100K to 10K interface with latch CERDIP16	Philips
100179	100179	High speed carry look ahead generator CERDIP24	Philips
1007	LT1007	LO NOISE PREC. OP AMP*, pinout	Maxim
101	BIO101cex	NTSC* to VGA converter, pinout	Biosoft
101	KMZ10A1	Magnetic field sensor, pinout	Philips
101	PCC101	(triple*) DES (with modes ECB, CBC, CFB, OFB) , pinout	Pijnenburg Custom Chips
10102	MC10H102	QUAD* 2-INPUT NOR* GATE, pinout	Motorola
10103	MC10H103	QUAD* 2-INPUT OR* GATE, pinout	Motorola
10104	MC10H104	QUAD* 2-INPUT AND* GATE, pinout	Motorola
10105	MC10H105	TRIPLE* 2-3-2 INPUT OR*/NOR* GATE, pinout	Motorola
10106	MC10H106	TRIPLE* 4-3-3 INPUT NOR* GATE, pinout	Motorola
10107	MC10H107	TRIPLE* 2-INPUT EXCLUSIVE-OR/EXCLUSIVE-NOR, pinout	Motorola
10109	MC10H109	TRIPLE* 4-5-INPUT OR*/NOR* GATE, pinout	Motorola
10113	MC10H113	QUAD* EXCLUSIVE OR* GATE, pinout	Motorola
10115	MC10H115	QUAD* LINE RECIEVER, pinout	Motorola
10116	MC10H116	see MC10216
10116	MC10H116	TRIPLE* LINE RECIEVER, pinout	Motorola
10117	MC10H117	DUAL* 2-WIDE 2-3-INPUT OR-AND/OR-AND INVERT GATE, pinout	Motorola
10118	MC10H118	DUAL* 2-WIDE 3-INPUT OR-AND GATE, pinout	Motorola
10119	MC10H119	4-WIDE 4-3-3-3-INPUT OR-AND GATE, pinout	Motorola
1012	CXK1012	eeprom*, pinout	sony
10121	MC10H121	4-WIDE OR-AND/OR-AND INVERT GATE, pinout	Motorola
10123	MC10H123	4-3-3 INPUT BUS DRIVER, pinout	Motorola
10125	MC10H125	QUAD* MECL-TO-TTL TRANSLATOR, pinout	Motorola
1013	LT1013-N	DUAL* PREC. OP AMP*, pinout	Maxim
1013	LT1013-S	DUAL* PREC. OP AMP*, pinout	Maxim
10130	MC10H130	DUAL* LATCH, pinout	Motorola
10131	MC10H131	DUAL* D-TYPE MASTER SLAVE FLIP-FLOP, pinout	Motorola
10135	MC10H135	DUAL* J-K MASTER SLAVE FLIP-FLOP, pinout	Motorola
10136	MC10H136	UNIVERSAL HEXADECIMAL COUNTER, pinout	Motorola
10141	MC10H141	FOUR-BIT UNIVERSAL SHIFT REGISTER, pinout	Motorola
10145	MC10H145	16 x 4 BIT REGISTER FILE (RAM), pinout	Motorola
1015	UMA1015M	Frequency Synthesiser, pinout	Philips
10151	UMA1015C1	Frequency Synthesiser, pinout	Philips
10158	MC10H158	QUAD* 2-INPUT MULTIPLEXER (NON-INVERTING), pinout	Motorola
1016	LT1016	Ultra Fast Precision Comparator, pinout
1022	TDA1022	BUKET BRIGADE DELAY LINE, pinout	Philips
1023	TDA1023	Proportional-control triac trigger circuit DIL16	Philips
1027	SAA1027	stepper motor driver, pinout
1029	SAA1029	Universal industrial logic interface DIL16	Philips
103	INA103	Low Noise, Low Distortion Instrumentation Amplifier, pinout	Burr-Brown
103	PGA103	Programmable Gain Amplifier, pinout	Burr-Brown
1035	DS1035	Unknown, PS	Dallas*
104	XTR104	4-20mA Current Transmitter with Bridge excitation and linearization, pinout	Burr-Brown
1042	LTC1042	Window Comparator, pinout
1042	SAA1042	Stepper Motor Driver, pinout	Motorola
1044	MAX1044-A	SW CAP VOLTAGE CONVERTER, pinout	Maxim
10474	10474	SRAM*, pinout	Synertek
105	INA105	Precision Unity Gain Differential Amplifier, pinout	Burr-Brown
105	PLS105	Programmable logic sequencer DIL28	Philips
105	PLS105A	Programmable logic sequencer DIL28	Philips
105	PLUS105-45	Programmable logic sequencer DIL28, DIL28SK	Philips
105	PLUS105-55	Programmable logic sequencer DIL28, DIL28SK	Philips
105	PLUS105-70	Programmable logic sequencer DIL28, DIL28SK	Philips
106	INA106	Precision Gain=10 Differential Amplifier, pinout	Burr-Brown
1060	TDA1060	Control circuit for SMPS DIL16	Philips
1060	TDA1060A	Control circuit for SMPS DIL16	Philips
1060	TDA1060B	Control circuit for SMPS CERDIP16	Philips
1064	SAA1064	4-digit LED driver with I2C* bus, pinout	Philips
1064	SAA1064	I2C* 4-digit LED driver, pinout	Philips
1064	TLS106-4	scr 4a 400v sens gate	ST
1075	DS1075	Unknown, see link, PS	Dallas*
1084	LT1084CT	=EZ1084 reg TO220, 5A Low Drop	order from Barend
1096	LTC1096	Micropower Sampling 8-Bit Serial I/O A/D Converter, pinout	Linear Technology
10968	LTC1096CN8	8 Bit Serial A-D Converter, pinout	Linear Technology
10988	LTC1098CN8	8 Bit 2 Channel Serial A-D Converter, pinout	Linear Technology
11	ATtiny11	Microcontroller, pinout	Atmel
110	KM110B_1	Magnetic field sensor, pinout	Philips
110	KM110B_2	Magnetic field sensor, pinout	Philips
110	KM110B_4	Magnetic field sensor, pinout	Philips
110	MAX110	adc*, pinout	maxim
1101	SAA1101	Universal Sync* Generator, pinout	Signetics
1103	HFA1103IP	Video Op Amp* & High Speed Sync* Stripper, pinout	Harris
11098	LT1109cn8-12	reg step up switching 5v-12v	LT
111	INA111	High-speed FET-Input Instrumentation amplifier, pinout	Burr-Brown
111	LM111	, pinout
115	mk115	www.icst.com/pdf/mk115.pdf	ICS*
1150	mk1150A	www.icst.com/pdf/mk1150A.pdf	ICS*
1150	mk1150B	www.icst.com/pdf/mk1150B.pdf	ICS*
1154	mk1154	www.icst.com/pdf/mk1154.pdf	ICS*
117	INA117	High Common-Mode Voltage Difference amplifier, pinout	Burr-Brown
1178	LT1178	17UA DUAL* PREC. OP AMP*, pinout	Maxim
118	FX118	Scrambler, pinout	CML
1180	TDA1180P	TV Horz. Processor, pinout	SGS
119	LM119_DIP14	Highspeed dual* comparator, pinout	National Semiconductor
119	LM119_PQFP20	Highspeed dual* comparator, pinout	National Semiconductor
1192	MSC1192	amplifier, pinout	Oki
12	ATtiny12	Microcontroller, pinout	Atmel
120	MAX120	12bit 500Ksps ADC, pinout	Maxim
1201	LM1201N	Monochrome CRT* Amp*, pinout	NS
1202	MAX1202	8 Channel 12bit ADC, pinout	Maxim
1203	DS1203	MicroPower Receiver Chip,	Dallas*
1203	LM1203N	RGB CRT* Amp*, pinout	NS
1203	MAX1203	8 Channel 12bit ADC, pinout	Maxim
1204	MAX1204	8 Channel 10bit ADC, pinout	Maxim
1205	LM1205N	130MHz RGB CRT* Amp*, pinout	NS
1208	DAC1208	12-bit multiplying, Microprocessor-compatable, Double-buffered DAC, pinout	NS
1210	ADS1210	24-bit Analog to Digital converter, pinout	Burr-Brown
1211	ADS1211	24-bit Analog to Digital Converter, pinout	Burr-Brown
1211	ADS1211E	24-bit Analog to Digital Converter, pinout	Burr-Brown
1217	DS1217A	Nonvolatile Read/Write Cartridge, PS	Dallas*
1217	DS1217M	Nonvolatile Read/Write Cartridge, PS	Dallas*
1218	DS1218	Nonvolatile Controller, PS	Dallas*
122	MAX122	12bit 333Ksps ADC, pinout	Maxim
1225	DS1225	8Kx8 Nonvolatile SRAM*, pinout	Dallas
1227	DS1227	KickStarter Chip, PS	Dallas*
1227	DS1227	KickStarter Chip,	Dallas*
1230	DAC1230	12-bit Multiplying, Microprocessor compatable,Dual-Buffered DAC, pinout	NS
1232	ADM1232	Microprocessor Supervisory Circuit, data	AD
1232	DS1232	MicroMonitor Chip,	Dallas*
1232	MAX1232	Microprocessor Monitor, pinout	Maxim
1233	DS1233	5V EconoReset, data	Dallas*
1236	DS1236A	MicroManager Chip, pinout	Dallas
1240	MAX1240	ADC 12bit, pinout	Maxim
1241	MAX1241	ADC 12bit, pinout	Maxim
1242	MAX1242	ADC 10bit, pinout	Maxim
1243	MAX1243	ADC 10bit, pinout	Maxim
1245	MAX1245	8 Channel 12bit ADC, pinout	Maxim
1250	DS1250	Key Ring, PS	Dallas*
12508	PIC12C508	8-BIT MICROCONTROLLER, pinout	MICROCHIP
12508	PIC12C508	General microcontroller but know to a lot of gamers because