Analog technologies Atls100ma103 User manual

2352 Walsh Ave. Santa Clara, CA 95051. U. S. A. Tel.: (408) 748-9100, Fax: (408) 748-9111 www.analogtechnologies.com

nalog Technologies ATLS100MA103

Low Noise Constant Current Laser Controller

Figure 1. Physical Photo of ATLS100MA103S

FEATURES

Ultra Low Noise: ≤6µAP-P and 1µARMS @0.1Hz to 10Hz

Output Current without Heat Sink: 100mA

High Absolute Accuracy: <0.1%

High Stability: <100ppm/°C

Programmable Current Limit through Separate Port

Complete Shielding

Compact Size

100 % Lead (Pb)-free and RoHS Compliant

DIP and SMT Packages Available

APPLICATIONS

Driving laser diodes with low noise, including DPSSL,

EDFA, SOA, fiber laser, direct diode lasers, etc.

DESCRIPTION

The ATLS100MA103 is an electronic module designed for

driving diode lasers with up to 100mA low noise current.

Figure 1 shows physical photo of ATLS100MA103.The

output voltage is 1.5V to 4V when powered by a 5V power

supply. you don't have to

When the maximum power consumed by the controller is

maintained to <1W, it does not require a heat sink to operate.

The controller has temperature compensation network so

that the output current maintains the same even as the

controller temperature rises.

In case the controller temperature exceeds a preset limit, 120°C,

the controller will be shutdown by itself to prevent the

controller from being damaged by the over heat.

The output current of the ATLS100MA103 can be set by an

input voltage linearly or modulated by an external signal of up

to 2MHz in bandwidth, resulting in a minimum 1μS rise and

fall times at the output current.

A highly stable low noise 2.5V reference voltage is provided

internally for setting the output current. This reference can also

be used as the voltage reference for external ADCs (Analog to

Digital Converters) and/or DACs (Digital to Analog

Converters) which are utilized for converting the analog signals,

such as LIO which represents the output current, into digital

signals, and/or converting the digital signals into analog ones

for setting the analog voltages, such as LIS which sets the

output current.

The ATLS100MA103 is packaged in a 6 sided metal enclosure,

which blocks EMIs (Electro-Magnetic Interferences) to prevent

the controller and other electronics from interfering each other.

There are 2 packaging versions available: DIP through hole

package and surface mount type.

Warning: Both the surface mount and the through hole

types of modules can only be soldered manually

on the board by a solder iron of < 310ºC (590ºF),

not go through a reflow oven process.

Figure 2. Pin Names and Locations

Figure 2 is the actual size top view of the ATLS100MA103,

which shows the pin names and locations. Its thickness is 5mm.

Table 1 shows the pin function descriptions.

Table 1. Pin Function Descriptions

Pin # Pin Name Pin Type Description

1 SDN Digital input

For ATLS100mA103: Shut down control. Negative logic. When the voltage is <0.7V,

shutdown on; when the voltage is >1 V, shutdown off.

For ATLS100mA103-PD: Shut down control. Positive logic. There is a pull-down

resistor of 100K to the ground.

2 GND Signal ground Signal ground pin. Connect ADC and DAC grounds to here.

VPS

PGND

LDA

TMPO

LPGD

GND

2.5V

LILM

LIS

LIO

SDN 1

14.5

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nalog Technologies ATLS100MA103

Low Noise Constant Current Laser Controller

3 2.5VR Analog output

2.5V reference voltage. It is used by the internal DACs as the reference voltage. It can

source 3mA max, with 5μVp-p noise @ 0.1 to 10 Hz and 25ppm/°C stability max.

4 LILM Analog input Laser current limit set. 0V to 2.5V sets the laser current limit from 0 to 110mA linearly.

5 LIS Analog input Laser current set. 0V to 2.5V sets the laser current from 0 to 100mA linearly.

6 LIO Analog output

Laser current output indication. 0V to 2.5V indicates the laser current of from 0A to

100mA linearly.

7 LPGD Digital output

Loop good indication. When the controller is working properly, this pin is pulled high.

Otherwise, it is pulled low.

8 TMPO Analog output The driver internal temperature indication output. Operating internally temperature.

9 LDA Analog output

Laser diode anode. Connect it to the anode of the laser diode. This pin is used to drive a

laser of which the cathode is connected to the case and the case is connected to the

ground. See below Figure 4.1, 4.2 or Figure 5.

10 LDC Analog output

Laser diode cathode. Only connect to the cathode of the laser diode. See below Figure

4.1, 4.2 or Figure 5.

11 PGND Power ground Power ground pin. Connect it directly to power supply return rail.

12 VPS Power input Power supply. The driver works from 3.0V to 5.5V.

SPECIFICATIONS

Table 2. Characteristics (Tambient = 25°C)

Parameter Value Unit/Note

Maximum output current 100 mA

Output current noise

(0.1Hz to 0.5MHz RMS) <1 μA

Current set voltage range 0 ~ 2.5 V

Current limit set voltage range 0 ~ 2.5 V

Modulation response bandwidth 1 MHz

Minimum drop out voltage 0.3 +

5×Iout V

Power supply voltage range 3.0 ~ 5.5 V

Operating case temperature −40 ~ 85 °C

Rise and fall times 300 nS

OPERATION PRINCIPLE

The block diagram of the controller is shown in Figure 3.

The shut down control circuit is activated under one of these

3 circumstances: external shut down, output current exceeds

the current limit, and the internal temperature exceeds

120°C.

When the controller is shut down by the external shutdown

signal, it will restart upon detecting the releasing of the

shutdown signal.

When it is shut down by the over current limit, the controller

shuts down itself and restarts again by going through the

soft-start process immediately. Therefore, the output current

has a saw-tooth waveform: quick shut down, slow and ramp

up.

When the controller is shut down by the over temperature, it

will wait till the temperature goes below the temperature limit,

120°C. Usually it takes a few or tens of seconds for the

controller to cool down before it restarts itself, depending on

the thermal mass of the controller and its surrounding

mechanical parts attached thermally, such as the PCB and its

traces, the heat-sinks if any, etc.

When controller is shut down, the voltage reference is also shut

down.

TMPO

Laser

Diode

LDC

LIS

Shut-

down

& soft-

start

circuit

Current

sensor &

low noise

driver

Voltage

reference

LISL

GND

SDN

10pF

100KΩVPS

PGND

LIO

LILM

LPGD

Temp.

sensor

LDA

Current

limiter

Figure 3. Block Diagram

APPLICATIONS

Figure 4.1 and 4.2 shows a typical application circuit. W1 and

W2 set the output current limit and output current respectively.

Resistor R1 and capacitor C1 form a low pass filter, to lower

2.5V

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nalog Technologies ATLS100MA103

Low Noise Constant Current Laser Controller

the noise from the voltage reference.

Laser diode D1 is connected between LDA and PGND. It is

worth mentioning that the power supply return terminal

should be connected to the pin 11 PGND and the cathode of the

laser diode should be connected to the pin 10 PGND. These 2

nodes should not be connected together externally and they are

connected together internally already by the controller.

Power Supply 0V

(Clock-wise)

Power Supply 5V

S1 SPST

Laser Diode

Shut Down

Loop Good Indication

Current Limit Set

LIO

VPS 12

PGND 10

LPGD 7

LDA 9

GND

LIS

PGND 11

TMPO 8

2.5VR

LILM

SDN

Laser Controller

1 2

1uF to 10uF

Current Set

To ADC

(Clock-wise)

20K

1 2

R1 1M 2 1

D2 LED

Figure 4.1 Typical Stand-alone CW Operation Schematic for ATLS100mA103

Power Supply 0V

(Clock-wise)

Power Supply 5V

S1 SPST

Laser Diode

Shut Down

Loop Good Indication

Current Limit Set

LIO

VPS 12

PGND 10

LPGD 7

LDA 9

GND

LIS

PGND 11

TMPO 8

2.5VR

LILM

SDN

Laser Controller

1 2

1uF to 10uF

Current Set

To ADC

(Clock-wise)

20K

1 2

R1 1M 2 1

D2 LED

Figure 4.2. Typical Stand-alone CW Operation Schematic for ATLS100mA103-PD

Turning the Controller On and Off

The controller can be turned on and off by setting the SDN

pin high and lower respectively. It is recommended to turn

the controller on by this sequence:

To turn on: For ATLS100mA103, turn on the power by

providing the power supply voltage to the controller, turn on

the controller by releasing the SDN pin. For

ATLS100mA103-PD, turn on the power by providing the

power supply voltage to the controller, turn on the controller

by connecting the SDN pin to VPS.

To turn off: turn off the controller by lowering the voltage

of SDN pin, turn off the power by stopping the voltage

supply on the VPS pin.

When not controlling by the SDN pin: leave it unconnected

and turn on and off the controller by the power supply.

In Figure 4.1 and 4.2, S1 is the shut down switch. For

ATLS100mA103, the internal equivalent input circuit of

SDN pin is a pull-up resistor of 100K being connected to

VPS in parallel with a 10pF capacitor to the ground. For

ATLS100mA103-PD, the internal equivalent input circuit of

SDN pin is a pull-down resistor of 100K being connected to

the ground in parallel with a 10pF capacitor to the ground. The

switch S1 can also be an electronic switch, such as an I/O pin

of a micro-controller, with an either open drain or push/pull

output. If not using a switch (S1) to control the laser, leave the

SDN pin unconnected. D2 is an LED, indicating when the

control loop works properly, that is: the output current equals

to the input set value. This pin has an internal pull up resistor

of 5K to the power supply pin, VPS, pin 10. The pull down

resistance is 200Ω. This 5K resistor can drive a high efficiency

LED directly. When higher pull up current is needed for

driving such as a higher current LED, an external resistor can

be placed between the VPS and the LPGD pins. Make sure

that the resistor is not too small that the pull down resistor will

not be able to pull the pin low enough when the controller loop

is not good. When choosing not to use an LED for indicating

the working status, leave the LPGD pin unconnected.

The LPGD pin can also be connected to a digital input pin of a

micro-controller, when software/firmware is utilized in the

system.

LDC

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nalog Technologies ATLS100MA103

Low Noise Constant Current Laser Controller

Setting the Output Current

The output current limit is set by adjusting W1, which sets

input voltages of LILM, pin 4. The output current will be:

I_output = 110 ×LILM (V)/2.5V (mA).

LILM should never be left float. Otherwise, the output

current limit may be set to too high a value that the laser

might be damaged.

The output current is set by adjusting W2, which sets input

voltages of LIS, pin 5. The output current will be:

I_output = 100 ×LIS (V)/2.5V (mA).

When no modulation is needed, it is suggested to use an RC

low-pass-filter, the R1 and C1 in Figure 4.1, to lower the

AC noise from the voltage reference source. The time

constant of this filter can be between a few to 10’s of

seconds. The bigger the time cost, the lower the output noise,

but the longer time will be needed to wait the output current

to go up.

Both of LILM and LIS, only LIS, can be configured by

using a DAC, to replace the W1 and W2 in Figure 4.1. Make

sure that the DAC has output low noise, or, if no modulation

is needed, an RC low pass filtered by be inserted between the

DAC and the LIS pin, similar as shown in Figure 4.1.

The LIS allows modulating the output current by a signal of up

to 2MHz in bandwidth. That is, when using a sinewave signal

to modulate the LIS pin, the output current response curve will

be attenuated by 3dB, or 0.71 times the full response

magnitude in current. When using an ideal square-wave to

modulate the output current at the LIS pin, the rise and fall

time of the output current will be about 1μS.

When the modulation signal is a square-wave and low output

noise is require, the low-pass-filter can still be used for

lowering the output noise. Figure 5 shows such a circuit. The

resistor R1 can be between 10K and 1M, depending on the

error voltage caused by the switch leakage current. The LILM

pin can be set by a POT as shown in Figure 4 or connect to

2.5VR.

It is recommended not to set the LIS pin to 0V, but keep

it >0.05V at all the time. The reason is that the laser diode

usually has a junction voltage of 2.5V, when setting the LIS

pin voltage to 0V, the output voltage will warble between 0V

and 2.5V, cause some oscillation slightly.

Power Supply 0V

Power Supply 5V

Laser Diode

Loop Good Indication

Current Limit Set

LIO

VPS 12

PGND 10

LPGD 7

LDA 9

GND

LIS

PGND 11

TMPO 8

2.5VR

LILM

SDN

Laser Controller

1 2

1uF to 10uF

Current Set

To ADC

20K

1 2

R1 100K

Digital Modulation Signal Input

S1 SPDT

To Microcontroller

2 1

D2 LED

(Clock-wise)

Figure 5. Low Noise Digital Modulation Circuit

The LIO can still be used to monitor the output current when

the LIS is modulated. The bandwidth of the LIO signal

is >10MHz, more than enough for monitoring output current

modulated by the LIS signal.

Figure 6. Relationship between VPS and LDAMAX

Maximum LDA Output Voltage vs. Power Supply Voltage

The maximum LDA pin output voltage is depending on the

power supply input voltage, VPS. Their relationship is shown

in Figure 6. Therefore, it is recommended that:

VPS ≥V_LD_max + 1V,

Where V_LD_Max is the laser diode’s maximum possible

forward voltage at the operation current.

Monitoring the Output Current

The output current of the controller can be monitored by

measuring the voltage on the LIO pin. This feature is very

useful for micro-controller based system where the ADC is

available and monitoring the current in real time is required.

This pin provides a very low noise voltage signal which is

proportional to the output current:

LIO (V) = I_out ×25 (V).

LDC

VPS(V)

LDAMAX

(V)

5.543.3

2.6

3.3

4.9

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nalog Technologies ATLS100MA103

Low Noise Constant Current Laser Controller

For example, when the output signal equals to 2.5V, the

output current is 100mA.

The output impedance of this pin is 10Ωand it can be used

to drive an ADC directly.

It can also be measured by a multimeter during debugging

process.

Figure 7 below shows the relations among LIS, LIMS and

IOUT

Figure 7. LIS & LIO

When LIS ≤LIMS, IOUT changes with LIS linearly; when LIS

＞ILMS, IOUT oscillates between 0 and LIMS

Monitoring the Controller Internal Temperature

The controller internal temperature can be monitored by

measuring the TMPO pin voltage. The relationship between the

LMPO voltage and the temperature is:

)(

479.3

8015.1

4182.21004.1525 3C

TMPO

T°

−

++−= (1)

where TMPO is the voltage on the TMPO pin.

This formula can be approximated by a linear equation:

)(31.907.192 CTMPOT °×−= (2)

Within the most commonly used temperature range of between

0°C to 100°C, the maximum error occurs at about 1.5V, at

which the temperature error between the calculated data by

using the formula (1) and the approximated data obtained by

using the linear equation (2) is about 0.4°C, with the linear data

being a little lower. The curves of the 2 sets of the data are

plotted in Figure 13.

Please notice that the TMPO pin has a weak driving

capability: the maximum sourcing current is 1μA and the

maximum sinking current is 40μA.

The TMPO pin can also be used as an input control pin: when

forcing the TMPO voltage to below 0.4V, the laser controller

will be shutdown.

Controller Power Consumption

The power consumption of the controller can be calculated by:

P_controller = I_output ×(VPS – VLDA),

where I_output is the output current;

VPS is the power supply voltage;

VLDA is the voltage across the laser diode.

When the P_controller exceeds 1W, a heat sink might be

needed. Under this situation, if prefer not to use the heat sink,

this is an option: lowering the controller power consumption

by reducing the power supply voltage VPS. Please make sure:

VPS ≥V_LD_max + 1V,

where V_LD_max is the maximum possible laser diode

voltage.

First Time Power Up

Laser is a high value and vulnerable device. Faults in

connections and damages done to the controller during

soldering process may damage the laser permanently.

To protect the laser, it is highly recommend to use 3 to 4

regular diodes of >100mA to form a “dummy laser” and insert

it in the place of the real laser diode, when powering up the

controller for the first time. Use an oscilloscope to monitor

the LDA voltage at times of power-up and power-down, make

sure that there is not over-shoot in voltage. At the same time,

use an ammeter in serious with the dummy laser, to make sure

that the output current is correct.

After thorough checking free of faults, disconnect the dummy

laser and connect the real laser in place.

The controller output voltage range for the laser is between

0.5 to 4V when powered by a 5V power supply.

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nalog Technologies ATLS100MA103

Low Noise Constant Current Laser Controller

Figure 8. Driving High Voltage Laser Diodes

Driving High Voltage Laser Diodes

Some laser diodes have high forward voltage, such as 7V,

while the laser driver ATLS1A103D has a maximum output

voltage of 4V. This section tells a way to drive such laser

diodes by using this laser driver.

The schematic is show as in Figure 8. Where Power Supply

1 is the power supply for the laser driver, Power Supply 2 is

for increasing the laser driver's maximum output voltage.

Please notice that the power on sequence has to be in this

way: turn on Power Supply 1, turn on Power Supply 2, then

turn on the laser driver by driving SDN (Shutdown) pin to

logic high.

The sequence for turning off the laser circuit is: turn off the

SDN pin by pulling it down to the logic low, turn off Power

Supply 1, then, turn off power supply 2.

To make sure the circuit works ok: turn on the laser,

measure LDA voltage, it should be between 1V to 3V, at

room temperature, the ideal LDA voltage is around 2V.

MECHANICAL DIMENSIONS AND MOUNTING

The ATLS100MA103 comes in 2 packages: through hole

mount and surface mount. The former is often called DIP

(Dual Inline package) or D (short for DIP) package and has

a part number: ATLS100MA103D, and the latter is often

called SMT (Surface Mount Technology) or SMD (Surface

Mount Device) package and has a part number:

ATLS100MA103S. See below Figure 9 and 10.

Figure 9. Dimensions of the DIP Package Controller

Figure 10. Dimensions of the SMT Package Controller

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nalog Technologies ATLS100MA103

Low Noise Constant Current Laser Controller

Figure 11 shows the foot print which is seen from the top side of the PCB, therefore, it is a “see through” view.

Figure 12 shows the view of the bottom side PCB foot-print.

“Tent” (i.e. cover the entire via by the solder mask layer) all the vias under the controller, otherwise, the vias can be shorted by

the bottom plate of the controller which is internally connected the ground.

Please notice that, in the recommended foot print for the DIP package, the holes for pin 2 to 6, and 8 to 12 have larger holes

than needed for the pins. This arrangement will make it easier for removing the controller from the PCB, in case there is a

rework needed. The two smaller holes, for pin 1 and 7, will hold the controller in the right position.

It is also recommended to use large copper fills for VPS, PGND, and the LDC pins, and other pins if possible, to decrease the

thermal resistance between the module and the supporting PCB, to lower the module temperature.

Please be notice that the SMT version cannot be soldered by reflow oven. It must be soldered manually.

1.5 ×14

1.0 ×12 0.8 ×2

14.5

2 ×14

R1.0 ×4

PCB Copper

without solder pad

PCB Hole

Orientation Mark Outline

Figure 11. Top Side PCB Foot-print for the DIP Package

3.0 ×14

1.5 ×14

PCB Copper

with solder pad

Figure 12. Top View of the Bottom Side PCB Foot-print

Figure 13. Controller Internal Temperature vs. TMPO Voltage

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nalog Technologies ATLS100MA103

Low Noise Constant Current Laser Controller

ORDERING INFORMATION

Table 3. Part Number

Part # Description

ATLS100MA103D Controller in DIP package

ATLS100MA103S* Controller in SMT package*

ATLS100MA103-PD Controller with a pull-down resistor of 100K to the ground.

WARNING: Both the surface mount and the through hole types of modules can only be soldered manually on the

board by a solder iron of < 310ºC (590ºF), not go through a reflow oven process.

NOTE: The power supply may have overshoot, when happens, it may exceed the maximum allowed input voltage, 6V,

of the controller and damage the controller permanently. To avoid this from happening, do the following:

1. Connect the controller solid well with the power supply before turning on the power.

2. Make sure that the power supply has sufficient output current. It is suggested that the power supply can

supply 1.2 to 1.5 times the maximum current the controller requires.

3. When using a bench top power supply, set the current limit to >1.5 times higher than the maximum current

the controller requires.

PRICES

Table 4. Unit Price

Quantity 1 −9 10 −49 50 −199 200-499 ≥500

ATLS100MA103D

ATLS100MA103D-PD

ATLS100MA103S

ATLS100MA103S-PD

$68.0 $65.3 $61.5 $57.8 $54.0

NOTICE

1. ATI warrants performance of its products for one year to the specifications applicable at the time of sale, except for those

being damaged by excessive abuse. Products found not meeting the specifications within one year from the date of sale can

be exchanged free of charge.

2. ATI reserves the right to make changes to its products or to discontinue any product or service without notice, and advise

customers to obtain the latest version of relevant information to verify, before placing orders, that information being relied

on is current and complete.

3. All products are sold subject to the terms and conditions of sale supplied at the time of order acknowledgment, including

those pertaining to warranty, patent infringement, and limitation of liability. Testing and other quality control techniques are

utilized to the extent ATI deems necessary to support this warranty. Specific testing of all parameters of each device is not

necessarily performed, except those mandated by government requirements.

4. Customers are responsible for their applications using ATI components. In order to minimize risks associated with the

customers’ applications, adequate design and operating safeguards must be provided by the customers to minimize inherent

or procedural hazards. ATI assumes no liability for applications assistance or customer product design.

5. ATI does not warrant or represent that any license, either express or implied, is granted under any patent right, copyright,

mask work right, or other intellectual property right of ATI covering or relating to any combination, machine, or process in

which such products or services might be or are used. ATI’s publication of information regarding any third party’s products

or services does not constitute ATI’s approval, warranty or endorsement thereof.

6. IP (Intellectual Property) Ownership: ATI retains the ownership of full rights for special technologies and/or techniques

embedded in its products, the designs for mechanics, optics, plus all modifications, improvements, and inventions made by

ATI for its products and/or projects.

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