Synectic Design was one of the first manufacturers to build digital amplifiers, and the depth of understanding and range that is offered reflects this

Synectic Design is renowned for the high quality and excellent value of its instrumentation amplifiers. Synectic was one of the first manufacturers to build digital amplifiers, and the depth of understanding and range that is offered reflects this. As the company has been working in this field for many years it understands the market in great depth, allowing it to provide its customers with what they need now and in the future.

Synectic design’s amplifiers can connect to various transducers including: strain gauges, pressure transducers, but are most commonly used with load cells.

Most load cells produce an analogue output signal, but increasingly many process control systems require a digital input, therefore the load cell signal needs to be digitised as well as amplified.

This is where a digital amplifier is required.

Digitisation of load cell signals provides increased accuracy, resolution and reduced noise interference of the signal.

Synectic Design’s digital amplifiers provide the digitisation and amplification function in one unit.

Many competing digital amplifiers require a digital junction box before the amplifier input.

The digital amplifiers also work with digital load cells, accepting a digital input and simply amplifying it, retaining accuracy and avoiding any loss of clarity due to noise interference.

Synectic Design offers five digital amplifiers, tailored for different requirements.

The SY016 is a completely self contained unit which will provide excitation for up to four 350R bridges.

The device’s built-in microcomputer calculates a temperature compensated 20bit value (signed), which is directly proportional to the load.

The SY016 has typical reading speed of 200Hz (limited by Windows) and communicates via RS232.

The SY036 is a cased self-contained unit that can be placed inline with a computer cable.

The unit has a 16bit processor and can be connected through RS232, RS485 or now via USB.

A logger option is available and it is possible to scale the output signal to many engineering units rather than purely the raw signal.

Synectic’s SY034 and SY044 are similar in terms of offering a high resolution 24bit processor, currently operating at a speed of up to 100Hz.

The unit connects to a PC via either RS232 or the more popular USB option.

The difference between the two units is that the SY034 is a single channel amplifier and the SY044 is a dual channel amplifier, where both channels read simultaneously.

Load cell amplifiers are each able to network up to 50 load cells with the added ability of logging to a PC or laptop with suitable logging software

Datum Electronics has an all-new range of load cell amplifiers that can be networked with a number of load cells or other full bridge sensors including pressure sensors and Datum’s very own Bolt-on sensor range. The Type 135 and Type 136 load cell amplifiers are each able to network up to 50 load cells with the added ability of logging to a PC or laptop with suitable logging software.

This can be achieved with the Datum Electronics NetDisp software, which displays and logs graphically the information provide by the load cell.

This is a windows based application suitable for most commercial available PC systems and controls.

Alternatively, there is also the option of using an existing user’s software.

NetDisp is a Windows PC based software package, designed to gather data from up to a total number of 50 load cells, connected to an RS485 network via Datum Electronics Type135, RS485 network strain gauge amplifiers.

Each Load Cell on the Network is individually calibrated to give an output in kilograms.

The software package sequentially reads the current load value from each cell and processes all load values to provide display and group sum functions.

The software allows for the load value of groups of cells to be summed together to give a total load for the group.

This total load is treated in the same way as individual cell load for display and alarm functions.

Housed within a die cast aluminium enclosure, these robust amplifiers are ideal for applications requiring a number of distributed strain sensors logged into a single PC with interface software.

Postamplifiers are intended for applications where the receiver optical subassemblies with low-cost/low-gain transimpedance amplifiers and/or PIN photodiodes are used

New from Micrel, the SY88343HL and SY88289HL are high-sensitivity low-power CML limiting postamplifiers, designed with twice the signal gain of Micrel’s existing devices. These solutions are targeted at applications using low-cost transimpedance amplifiers and/or low gain PIN diodes which occur in a wide variety of data and telecomms markets including PON, Gigabit Ethernet, SFP/SFF optical transceivers, 1x and 2x Fibre Channel, and Sonet/SDH: OC3/12/24/48 - STM 1/4/8/16 datarates.

Both devices are currently in volume production with pricing for 1000-unit quantities starting at US $2.49.

‘Higher gain, high-sensitivity post amplifiers exhibit better bit error rate (BER) performance as a result of bigger eye opening when detecting and receiving very weak signals’, says Thomas S Wong, Vice President High Bandwidth Products for Micrel.

‘These devices are recommended for systems that have stringent BER and low cost requirements’.

In a fibre optic module, the devices connect to typical transimpedance amplifiers (TIAs).

The linear signal output from TIAs can contain significant amounts of noise and may vary in amplitude over time.

The SY88289HL and SY88343HL quantise these signals and output them in low noise CML-level waveforms.

The SY88343HL and SY88289HL both feature high input sensitivity and can amplify input signals as small as 4mV peak-peak to drive CML/PECL devices.

The SY88343HL has the same footprint as all other Micrel postamplifiers, which allow for flexible upgrades and interchangeability.

These solutions also feature high-sensitivity loss-of-signal circuits which are ideal for detecting very small input signals.

The new postamplifiers are intended for applications where the receiver optical subassemblies (ROSAs) with low-cost/low-gain transimpedance amplifiers and/or PIN photodiodes are used.

The devices have wide bandwidth, high gain, and are optimised to operate over a wide range of datarates, from 155Mbit/s to 3.2Gbit/s.

Both Post Amplifiers have chatter-free open collector TTL LOS outputs with adjustable LOSlvl threshold.

The ICs can amplify as low as 4mv signals to drive devices with CML and PECL inputs.

Each device operates from a single 3.3V power supply, over temperatures ranging from -40 to +85C and comes in a tiny 3 x 3mm 16-pin MLF package.

Synectic Design is renowned for the high quality and excellent value instrumentation amplifiers produced, but now many process control systems require the digital input available from the latest units

Synectic Design is renowned for the high quality and excellent value instrumentation amplifiers they produce. Synectic were one of the first manufacturers to build digital amplifiers and the depth of understanding and range that is offered reflects this. As the company has been working in this field for many years we understand the market in great depth, this allows us to provide our customers with what they need now and in the future.

Synectic Design amplifiers can connect to various transducers including strain gauges and pressure transducers, but are most commonly used with load cells.

Most load cells produce an analogue output signal, but increasingly many process control systems require a digital input, therefore the load cell signal needs to be digitised as well as amplified.

This is where a digital amplifier is required.

Digitisation of load cell signals provides increased accuracy, resolution and reduced noise interference of the signal.

Synectic Design digital amplifiers provide the digitisation and amplification function in one unit, whereas many competitive digital amplifiers require a digital junction box before the amplifier input.

Our digital amplifiers also work with digital load cells, accepting a digital input and simply amplifying it, retaining accuracy and avoiding any loss of clarity due to noise interference.

Synectic Design offers five digital amplifiers, tailored for different requirements.

The SY016 is a completely self contained unit which will provide excitation for up to four 350R bridges.

The built-in microcomputer calculates a temperature compensated 20 bit value (signed), which is directly proportional to the load.

The SY016 has typical reading speed of 200Hz (limited by Windows) and communicates via RS232.

The SY036 is a cased self contained unit which can be placed inline with a computer cable.

The unit has a 16 bit processor and can be connected through RS232, RS485, or now via USB.

A logger option is available and it is possible to scale the output signal to many engineering units rather than purely the raw signal.

Synectic SY034 an SY044 are similar in terms of offering a high resolution 24 bit processor, operating at a speed of currently up to 100Hz.

The unit connects to a PC via either RS232 or the more popular USB option.

The difference between the two units is that the SY034 is a single channel amplifier and the SY044 is a dual channel amplifier, where both channels read simultaneously.

Our final digital amplifier is the SY056 which is due to be released soon.

The SY056 will use a 24 bit processor that will read data at a speed of up to 2.5MSamples per second.

The unit will connect to a PC via USB and transmit data at 400Hz when running in Windows or for ultimate performance over 500Hz when running on a Linux operating system.

A new family of zero-drift operational amplifiers are ideal for demanding applications in medical instrumentation, temperature measurement, test equipment, security and consumer systems

Providing an unmatched combination of precision, micropower and miniature packaging, Texas Instruments has a new family of zero-drift operational amplifiers. Featuring ultralow offset (2mV), ultralow quiescent current (17mA), operation down to 1.8V and SC70 or SOT23 packages, the OPA333 is ideal for demanding applications in medical instrumentation, temperature measurement, test equipment, security and consumer systems.

‘Texas Instruments has leveraged its expertise in analogue signal conditioning and process technology to deliver an ideal precision amplifier solution’, said Gregg Lowe, Senior Vice President of TI’s High-Performance Analogue Business.

‘The OPA333 will serve as a key building-block component in advanced, next-generation applications that demand an unmatched combination of precision, low power, low operating voltage and miniature packages’.

Fabricated using TI’s high-performance, precision mixed-signal CMOS technology, the OPA333 uses auto-zeroing techniques to simultaneously provide very low offset voltage and near-zero drift over time and temperature.

The device offers high-impedance inputs that have a common-mode range 100mV beyond both rails and rail-to-rail output that swings within 100mV of the rail.

Single or dual supplies as low as 1.8V and up to 5.5V may be used.

The OPA333 features excellent CMRR (common-mode rejection ratio) without the crossover errors associated with traditional complementary input stages.

This design results in superior performance for driving analogue-to-digital convertors (ADCs) without degradation of differential linearity.

The OPA333 family is available now from TI and its authorised distributors.

The OPA333 (single version) is packaged in the SC70, SOT23-5 and SO-8, and is priced at $0.95 in 1000 piece quantities (suggested resale pricing).

The OPA2333 (dual version) is offered in 3 x 3mm DFN and SO-8 packages, and is priced at $1.50 in 1000 piece quantities.

Offering dual duplex operation, ClearGain DD1900 Ground-Mounted Amplifier (GMA) incorporates fixed-gain, low-noise amplifier and high-performance filters. Without need for tower climbs, GMA improves signal quality by boosting uplink (RX) signal of mobile system. Amplifying full 1,900 MHz band, it consists of amplification module and power distribution unit, providing full compatibility with all base stations.

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The ClearGain GMA’s slim, modular, stackable design conserves rack space and is easy to install. These features minimize the cost of network expansion and improve the quality of service (QoS) that allow wireless operators to increase profitability from new and existing services.

In addition to the benefits a traditional ClearGain system provides, the ClearGain DD1900 Full Band GMA offers dual duplex operation and incorporates a highly advanced fixed-gain, low-noise amplifier (LNA) and high-performance filters for added reliability. The DD1900 Full Band GMA amplifies the full 1900 MHz band to maximize signal quality and optimize coverage.

“While subscribers are willing to pay a premium for data services, improved quality of service is necessary to provide new services,” said Bill Heuer, ClearGain product manager for ADC. “Due to the tradeoff between bit rate and bandwidth inherent to data services, improved signal quality is required in order to achieve the same level of performance at even higher data rates. With the improvement in signal quality that ADC’s ClearGain GMAs provide, customers will find significant value in this solution.”

ClearGain GMAs improve signal quality by boosting the uplink (RX) signal of a mobile system. GMAs perform this amplification with the low noise contribution, resulting in a substantial increase in receiver performance and an improvement in overall coverage. These improvements in QoS allow mobile subscribers to place more calls, make longer calls, and successfully complete calls in an expanded geographic area, resulting in increased revenue. The ClearGain GMA consists of an amplification module and a power distribution unit (PDU), providing full compatibility with all base stations.

Abstract An approach to the analysis of composite amplifiers is presented. It is based on programmes written in MATLAB that take advantage of the plotting and graphic user interfaces capabilities of the software package. This approach provides better results than simulator-based ones, because the behaviour of the circuits is explored iteratively.

Keywords composite amplifiers; frequency response; graphical user interfaces; stability analysis

All textbooks devoted to analogue design at the undergraduate level present the frequency response through the well-known Bode diagrams. Usually, the theoretical background and the procedures for drawing the diagrams are well presented.1 When dealing with amplifying stages built with operational amplifiers (op-amps), however, a major drawback of most books is that only simple cases, with a single op-amp, are considered. At best, the behaviour of cascaded stages is illustrated.2,3 As a result, students are not well prepared to deal with more complex topics, such as stability and compensation, or with circuits that include more than one op-amp in the same feedback loop.

On the other hand, the SPICE simulator has been widely used as a teaching aid and is quite successful in tasks such as quickly testing a design.4 This simulator, however, is not the best choice when it is desired to gain a clear understanding of the behaviour of a circuit. A case in point is the response of an unstable amplifier: the resulting Bode diagram will be correct, but information related to the causes of the instability will be lacking. Also, when it is desired to explore the effect of varying the value of one element (say, a resistor in the feedback network), the best option available is the parametric analysis, but interpreting the results can be confusing and time consuming.
Mathematical programs have long been used in control theory. Their main advantage is the capability to draw complex graphs. Since classic control theory evolved from stability analysis in early amplifiers, it seems natural to use control-oriented programmes to illustrate analogue design topics. The purpose of the paper is to present an approach to the analysis of amplifying stages with complex feedback networks,5 using the MATLAB program, and taking advantage of the graphic user interface (GUI) capabilities. This approach provides a better understanding than those based on simulators.

Composite amplifier with two op-amps

Conclusions

The analysis of two complex amplifier configurations is presented. Since the behaviour of the circuits is not apparent from the transfer functions, two programmes written in MATLAB are used as a learning tool. They take advantage of the graphic user interface capabilities of the software package, and provide a clear understanding of the relation between the frequency response and the main circuit parameters. It has been found that this approach provides better results that using circuit simulators alone. The Bode diagrams are quickly updated when any of the sliders is moved and the behaviour of the circuits can be explored iteratively. The screen layout design can be complicated; however, a special design tool included with the software package simplifies the process. Once the theoretical principles involved are understood, the amplifiers can be tested in a circuit simulator or, better still, in the lab.

Mechanics, removing, replacing and testing your Black Hawk’s AM-7106E/A stabilator amplifiers, NSN 5895-01-316-2763, may not rank high on your “things to do list.”

But when it’s time for shipping, packaging, handling or maintaining of the amplifier, it does matter what you do. A little TLC goes further than you think. Rough handling of the amplifiers after you remove them can damage the internal gyros. If that happens, the entire amplifier has to go to depot for repair.

And packaging components incorrectly can damage the external vents, fuse holders and internal gyros.

Always ship the amplifiers in their original container. If the originalcontainer is not available, use the container received with a new serviceable stabilator amplifier.

Audio Amplifiers

Any electronic device that increases the power of an electrical signal whose vibrations are confined to the audio frequency range—the range that can be perceived by the human ear—is an audio amplifier. All devices that transmit, record, or otherwise electronically process voice signals employ audio amplifiers. Voice-recognition or voice-synthesis systems, communications or eavesdropping devices, hearing aids, entertainment systems, talking toys, are examples of devices containing audio amplifiers.

The need for amplification. Acoustic or sound waves are longitudinal pressure waves (i.e., waves that cause molecules to oscillate along the wave's line of travel rather than across it) in air, water, or any other medium. A sound is said to be in the audio frequency range if it is not too high or low in frequency to be heard by the human ear. Audio sound waves may be converted by microphones into electrical signals for analysis, transmission, or recording. Electrical signals can also be converted by speakers into audible sound waves. Microphones and speakers are both transducers, that is, devices that convert energy from one form (e.g., electrical) into another (e.g., acoustic) or vice versa. Audio amplifiers are required with both microphones and speakers.

Input amplification. Amplification of the signal produced by a microphone—often termed preamplification—is necessary because the electrical signal that can be derived directly from sound waves impinging on a microphone is weak (i.e., on the order of .01 V or less; for eavesdropping applications, much less). Input signals of such low amplitude must be amplified before they can be processed in either analog or digital circuits.

In analog circuits—circuits that process smoothlyvarying electrical quantities—there is a always a certain amount of random electrical activity or "noise." This noise is mixed with any information signal processed by the circuit, corrupting it. Amplifying a weak input, such as that from a microphone, before it mingles with circuit noise makes the noise problem manageable. Furthermore, all analog circuits that lack amplification (passive filters, transmission lines, etc.) experience signal loss; that is, they dissipate energy. A weak signal fed into a circuit that does not contain amplification will, therefore, quickly disappear, making amplification necessary in most analog circuits. Finally, amplification provides electronic isolation between the signal being amplified and the result of the amplification process; among other gains, this simplifies the circuit-design process.

Output amplification. Wherever human ears are the ultimate destination of a signal it is necessary to drive a physical sound-making device at the output. Here audio amplification is needed for a reason complementary to that which applies at the input: the signal power needed to drive an output device (e.g., speaker or headphones) is greater than that conveyed by the signals processed throughout the circuitry of a typical electronic device, whether analog or digital. An audio amplifier is thus found at the output as well as at the input of almost every system handling signals in the audio range.

Applications. The number of audio amplifier designs that have been produced over the last century is probably in the hundreds of thousands. Such devices are a ubiquitous feature of modern life, and are found in computers, telephones, radios, high-fidelity audio systems, all military voice-communication systems, many appliances, and even toys.

Audio amplifiers can be miniaturized for placement in headsets, mobile phones. In applications where small size is at a premium, as in hearing aides and espionage applications (bugs and "wires"), they may be ultraminiaturized. At the high-power end, audio amplification drives public-address systems, speaker systems, and (potentially) weapons. Research is being conducted by several countries, including Russia and the U.S. (through its Low Collateral Damage Munitions Program), into the use of highly amplified sound as a weapon; frequencies in the infrasonic, audio, and ultrasonic ranges are all being considered for use against human beings. Though acoustic weapons are sometimes assumed to always be in the nonlethal category, sound can be irritating, painful, or fatal, depending on its intensity and on the efficiency with which its energy is coupled to the body.

Loud music has repeatedly been used as a psychological weapon in siege situations (e.g., by the U.S. Army against former Panamanian dictator Manuel Noriega in 1989, by cult leader David Koresh against police in 1993, and by Peruvian police during the hostage crisis at the Japanese Embassy in 1997) and as an instrument of torture. Specially-designed acoustic weapons can induce, among other effects, vomiting, choking, spasms, incontinence, thermal burns, intolerable sensations in the chest, injury to internal organs, and hearing damage. The latter is considered a serious drawback in antipersonnel applications, as hearing loss caused by intense sound is often partly or wholly permanent. Like laser weapons designed to blind (which have been outlawed by recent international agreement), acoustic weapons designed to deafen would violate international humanitarian law. Further, they would be vulnerable to obvious countermeasures, such as earplugs. Indeed, some scientists are skeptical about the possibility of developing reliable, affordable weapons of any kind from sound. However, research and development are proceeding.