月:2016年1月

analogtechnologies.com

High Voltage Laser Driver ATLSXA214

Laser driver with high output voltage is capable of driving one or more laser diodes simultaneously. The input voltage can be 5V to 16V, and the output voltage is from 0V to 15V. The laser driver generates ultra low output current noise : < 12µA@0.1Hz~10Hz, with high current stability <±600µA@4A &-20°C~80°C.
Though this laser driver comes with high efficiency >92%, it doesn’t need heat sink to dissipate heat, a small amount of heat.

The laser driver will shut down by itself when the temperature exceeds the temperature limit 120°C. Under shutdown mode, all the parts will stop working, while the input current is reduced to < 3µA. A loop good indication output is used to tell users if this laser driver is working well.

A high modulation speed can be achieved due to the output stage. There is an over current protection circuit in this laser driver, which prevents the laser driver from being damaged by over current. There is also a soft start circuit which allows the laser driver to increase its output current slowly during start up process and shut down the current quickly.

The physical photo of high voltage laser driver ATLS10A214

If you want to know more, please contact us.
For detailed information of laser drivers, please visit us at: http://www.analogtechnologies.com/atlsxa214.html

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ATE1-TC-199Series Thermal Cycling TEC Module

ATE1-TC-199 series thermal cycling TEC module comes with 199 pairs of Peltier elements inside. These TEC modules are designed to regulatethe target object temperature with high changing speed and stabilize the temperature with high precision. The thermal cycling TEC modules have a longer operational life than standard TEC modules since the service life of the standard TEC modules will be reduced significantly when they are exposed to demanding physical stresses as the module shifts from heating to cooling.
There are two TEC modules in this series, ATE1-TC-199-13A and ATE1-TC-199-13AS. The only difference between them is that the former is a non-sealed one and the latter is a sealed one. The maximum input voltage of the TEC modules is 27.4 Volt. The output current is 13A. The temperature difference is 72°C.
Thermal cycling TEC modules can work withTEC controllers, ntc thermistors, and heat sinks to build a temperature controlsystem.
Physical photo ofATE1-TC-199 series thermal cyclingTEC module
For more parameters and other information about this TEC module or more types of Peltier modules, please refer to the webpage and its datasheet:
For more related products, please visit our main website:
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Driving Laser Diodes with ATLS2A212D Laser Driver

Since the invention of laser diode, it has been widely used in many technical fields, such as telecommunications, industrial production, and measurement equipment. In order to make laser diodes work well, our company (ATI) has designed and released a laser driver with high voltage and constant current. There are various laser drivers in our company and users can select what they need.
Figure 1. The photo of the ATLS2A212D laser driver
ATLS2A212D laser driver is a typical laser driver, as shown in Figure 1. This driver has a maximum output current of 2A and a wide modulation bandwidth: DC ∼ 10 kHz. And it also has a wide output voltage range, 0.8~15V, which allows driving one or multiple laser diodes at the same time. During operation, little amount of heat will be generated, so there is no need of heat sinks. Moreover, the laser driver has a strong anti-interference capability because of being packaged in a metal enclosure.
If you want to know more about laser drivers, please visit our website at:
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Driving laser diodes with an electric module

In order to drive laser diodes, our company (ATI) has designed and produced an electric module, which is also called laser driver. And laser drivers released from our company features high stability, high efficiency, low noise and small size. There are many series laser drivers available and Figure 1 is the photo of a typical one.
Figure 1. The photo of a laser driver
By using a laser driver, many functions can be realized, such as laser current setting and monitoring, controlling loop good indication, switching working mode automatically and so on. Because of high efficiency, no heat sink is needed for normal operation. Moreover, the driver is packaged in a metal enclosure, so there is no interference.
By the way, our company has also designed a load assembly to emulate laser diodes for evaluating laser drivers. In this way, the cost can be reduced.
If you want to know more about laser drivers, please visit our website at:
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Noise Measurement Amplifier

An oscilloscope can measure noise, but for ultra low noise, such as nV and µV level noises, it’s hard to measure. There is anoise measurement amplifier ATNMA1.0, which is used to test and measure ultra low noise that can’t be measured by an oscilloscope.
This noise measurement amplifier can detect and amplify the noise signals by touching the selected point. There are seven magnifications, 10,000×, 30,000×, 100,000×, 300,000×, 1,000,000×, 3,000,000×, 10,000,000×. There are also three filter bandwidths available: : 0.1Hz ~ 10Hz, 0.1Hz ~ 1kHz, 0.1Hz ~ 100kHz.
There are several parts in this amplifier, a rechargeable battery, a coaxial cable and probes. The rechargeable battery can be used for over 20 hours. The battery capacity is 500mAh. The charging voltage is 4.2V. There is a function to monitor the battery capacity. When battery indicator switch is pressed, it’s easy to observe if the battery needs to be charged. There are several LEDs on the amplifier, which shows the capacity. Meanwhile, when the battery is being charged, there are two charging display LEDs.
The physical photo of Noise Measurement Amplifier ATNMA1.0
If you want to know more about this amplifier, please contact us.
Our web site is
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Advanced laser drivers in ATI

ATI is the abbreviation of Analog Technologies, Inc., which specializes in designing and releasing laser drivers, TEC controllers, SMD/SMT component kits, etc. Laser driver is a typical product of ATI, which is used to drive laser diodes with high stability, high efficiency, and low noise. And there is a wide variety of advanced laser drivers available, such asATLSXA212 series, ATLSXA214 series, ATLS_XXX_103 series and so on.
Figure 1. The photo of the ATLS1A212D laser driver
The above photo is a typical one of lasers drivers. This laser driver has high efficiency (more than 90%), so there is no heat sink for normal operation. And it contains three work modes: shutdown, standby and operation. Under different work conditions, the driver can automatically switch operation mode. Moreover, by using a laser driver, the actual current and temperature can be monitored in real time.
If you want to know more about laser drivers or other products, please visit our website at:
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New Peltier Controller TECA1-xV-xV-DAH

TECA1-xV-xV-DAH is a new peltier controller released by our company. Peltier controllers is widely used in regulating the object temperature by driving peltier modules (TEC modules) with high stability, high efficiency, high energy efficiency, zero EMI, and a compact package.

TECA1-xV-xV-DAHis an improved version of TECA1-xV-xV-D. The difference lies inTECA1-xV-xV-DAH has a higher accuracy, please refer to the table below.

Part # Maximum|VTEMP − VTEMPSP |(mV)
TECA1-xV-xV-DAH ≤0.5
TECA1-xV-xV-D ≤25

This table shows that the voltage difference between VTEMPand VTEMPSP ofTECA1-xV-xV-D is ≤25mV, while the voltage difference between VTEMPand VTEMPSP ofTECA1-xV-xV-DAH is ≤0.5mV, ten times lower than that of TECA1-xV-xV-D. Moreover, Offset Object temp. vs. set-point temp. of TECA1-xV-xV-DAHis ±0.004°C or ±0.5mV, while that of TECA1-xV-xV-D is±0.1°C or ±15mV. Thus, it’s easily seen that the TECA1-xV-xV-DAHperforms better than TECA1-xV-xV-D.

In the part number TECA1-xV-xV-DAH, the1st x indicates the power supply voltage, and it can be 3.3V or 5V; the 2nd x stands for the maximumoutput voltage across TEC, e.g. TECA1H-5V-5V-D. The above two specifications can be specified by the customers.

Figure 1. The physical photo of Peltier controllerTECA1-xV-xV-DAH

ATI provides more peltier controller products. If you want to know more about thisPelter controllers, please visit our website at:

  http://www.analogtechnologies.com/TECA1-xV-xV-DAH.html

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ATLSXA212D Series Laser Driver

ATLSXA212D series laser driver is an electric module with high voltage and constant current and it is designed and released by ATI. ATI is specializes in R&D and production of laser driver or laser controller. The VPS range of ATLSXA212D series laser driver is from 4.5V to 6V and its full swing output voltage is from 0.8V to VPS (input voltage). There are four maximum output currents available, namely 500mA, 1A, 2A and 3A. Figure 1 is the physical photo of the ATLS1A212D laser driver with maximum output current 1A, which is the typical one in ATLSXA212D series.
Figure 1. The photo of the ATLS1A212D laser driver
During operation, ATLSXA212D series laser driver can drive one or multiple serial laser diodes at the same time, and it has high efficiency, low noise, high stability and zero EMI (Electro-Magnet Interferences). This laser driver provides three work modes: shutdown, standby and operation. In addition, it comes with dedicated ports to monitor the actual laser current and temperature inside, and there is also a loop good indication to tell whether the driver works well.
If you want to know more about ATLSXA212D series laser drivers, please visit our website at:
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Thermoelectric Cooler Controller Design

This article is from Photonics Magazine. TEC controller design experts from Analog Tehcnologies, Inc offer tips to lower the cost and simplify the design of the devices, and to increase their ease of use.

Thermoelectric cooler (TEC) controllers are becoming more prevalent in thermal management designs because they can drive a thermoelectric cooler to stabilize the temperature of laser diodes or passive components used in communications equipment.

TECs have several advantages for temperature regulation: high accuracy and stability, fast response time, a wide set-point temperature range, and a simple structural design with no moving parts. Also, they are small and lightweight, reliable, noise-free and environmentally friendly. However, when comparing with temperature regulation approaches based on heat sinks or compressors, for applications requiring especially high thermal power output, TECs may have certain shortcomings: low efficiency, low thermal power, high cost of both TECs and controllers, and complex controller designs.

Figure 1. Thermoelectric coolers (TECs) are highly accurate and stable for temperature control, with a wide set-point temperature range and a simple packaging design with no moving parts. They are small and light, highly reliable, noise-free and environmentally friendly. Here, a structural diagram of a TEC.

Cold/hot sides and +/- terminals

In 1834, French physicist Jean-Charles Athanase Peltier found that the junctions of dissimilar metals are heated or cooled depending upon the direction in which an electric current passes through them. This effect became the Peltier effect.

A TEC has two ceramic plates with Peltier elements sandwiched in between. Based on the Peltier effect, these elements produce heat and cold by injecting an electric current through them. All the Peltier elements are connected in series; the first and last are each connected to a separate wire terminal. The plate on which the two terminals are mounted is often called the hot-side plate or simply the hot side; the other side is designated the cold-side plate or the cold side. The two sides are symmetrical in terms of thermal functionality, but the thermal load of the side with the terminals is a little higher because of the wire leads.

A DC current is injected into the TEC through the two terminals, and this generates a temperature difference between the two plates: One plate becomes cooler, while the other side becomes warmer.

When the cold side cools down, the TEC terminal connecting the positive lead of the power supply is designated as the plus (+) terminal, or the positive lead of the TEC; the other is designated as the minus (-) terminal, or the negative lead. As the DC current reverses direction – i.e., flows out from the plus terminal – the cold side will heat up and the hot side cool down. Therefore, TECs can be used both for cooling down and heating up the thermal load.

TECs can’t “generate” cold; they only move heat from one side to the other. They “produce” heat more efficiently than cold under the same size or current conditions because not all of the electric energy of the DC current is used for removing the heat; some energy is consumed by the Peltier elements and converted into heat, which is conducted to the two sides of the TEC at the same time. This heat boosts the heating-up power of the TEC but makes the cooling-down function less efficient.

http://www.analogtechnologies.com/a/New/Technology_innovation_related/2014/1219/88.htm

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ATE1-TC-127 Series Thermal Cycling TEC Module

ATE1-TC-127 series thermal cycling TEC modules come with high input voltage, 17.5V. There are several types of thermal cycling TEC modules in this series. The output currents are 5.5A, 5.7A, 8.5A, 7.8A and 12.1, each corresponding to a TEC module respectively. The temperature differences can be 72°C, 72.5°C and 74.5°C. The dimensions are not the same either.
These thermal cycling TEC modules are designed for temperature cycling applications. The operational life of standard TEC modules will be largely reduced when the TEC modules shift from heating to cooling. However, the thermal cycling TEC modules perform well during the shift and the service life is much longer than standard TEC modules. Therefore, it would be a perfect selection when the application needs TEC modules with long operation life.
Thermal cycling TEC modules can work with TEC controllers, ntc thermistors, and heat sinks to build a temperature control system.
Physical photo of ATE1-TC-127 series thermal cycling TEC module
For more parameters and other information about this TEC module or more types of Peltier modules, please refer to the webpage and its datasheet:
For more related products, please visit our main website: