Laser safety

System compliance

Alcatel-Lucent 1850 TSS-5 complies with the following laser safety regulations and standards:

This Product is designed to ensure that personnel operating the product are not endangered by laser radiation during normal operation and fault conditions. This product does not present a risk of eye injury because it is fully enclosed and does not contain embedded lasers greater than Class I/1 unless otherwise noted.

The following table shows the pluggable transmission module (PTM) laser safety specifications and the supported circuit packs. The following Class 1 SFP transceivers are Alcatel-Lucent approved.

Table 1-1: Pluggable transmission module laser safety specifications

Module Code

Supported Circuit Pack(s)

Wavelength

(nm)

Output Power

(dBm)

Fiber Type

(µm)

Connector Type

FDA Class/

IEC Class

100BASE-LX-I1

VLNC33

VLNC35

VLNC40

VLNC42

VLNC42B

VLNC60

VLNC61

VLNC62

VLNC64

1310

−8.0

Single Mode (9)

LC

I(LN50)/1

1000BASE-ZX-I1

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

1550

+5.0

Single Mode (9)

LC

I(LN50)/1

BASE-T-C1 electrical

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

NA

NA

NA

RJ45

NA

GE-1X2XFC-LX-I1

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1310

−3.0

Single Mode (9)

LC

I(LN50)/1

GE-1X2XFC-SX-I1

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

850

−2.5

Multimode (50 and 62.5)

LC

I(LN50)/1

GE-131T149R-I1

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1310 (TX)

1490 (RX)

+2.0

Single Mode (9)

LC

I(LN50)/1

GE-149T131R-I1

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1490 (TX)

1310 (RX)

+2.0

Single Mode (9)

LC

I(LN50)/1

OC3X12X48-IR1-I1

VLNC55

1310

-8.0

Single Mode (9)

LC

I(LN50)/1

OC3X12X48-LR1-I1

VLNC55

1310

0.0

Single Mode (9)

LC

I(LN50)/1

OC3IR1-I1

VLNC50

VLNC52

VLNC55

VLNC64

1310

-8.0

Single Mode (9)

LC

I(LN50)/1

OC3LR1-I1

VLNC50

VLNC52

VLNC55

VLNC64

1310

0.0

Single Mode (9)

LC

I(LN50)/1

OC12IR1-I1

VLNC50

VLNC52

VLNC55

1310

−8.0

Single Mode (9)

LC

I(LN50)/1

OC12LR1-I1

VLNC50

VLNC52

VLNC55

1310

+2.0

Single Mode (9)

LC

I(LN50)/1

OC12LR2-I1

VLNC50

VLNC52

VLNC55

1550

+2.0

Single Mode (9)

LC

I(LN50)/1

OC48LR1-I1

VLNC55

1310

+3.0

Single Mode (9)

LC

I(LN50)/1

OC48LR2-I1

VLNC55

1550

+3.0

Single Mode (9)

LC

I(LN50)/1

OC48SR1-I1

VLNC55

1310

−3.0

Single Mode (9)

LC

I(LN50)/1

622-131T155R-I1

VLNC50

VLNC52

VLNC55

1310 (TX) 1550 (RX)

+2.0

Single Mode (9)

LC

I(LN50)/1

622-155T131R-I1

VLNC50

VLNC52

VLNC55

1550 (TX) 1310 (RX)

+2.0

Single Mode (9)

LC

I(LN50)/1

S155I2

VLNC50

VLNC52

VLNC55

VLNC64

1310

−8.0

Single Mode (9)

LC

I(LN50)/1

S2G7C47LI

VLNC55

1471

+5.0

Single Mode (9)

LC

I(LN50)/1

S2G7C49LI

VLNC55

1491

+5.0

Single Mode (9)

LC

I(LN50)/1

S2G7C51LI

VLNC55

1511

+5.0

Single Mode (9)

LC

I(LN50)/1

S2G7C53LI

VLNC55

1531

+5.0

Single Mode (9)

LC

I(LN50)/1

S2G7C55LI

VLNC55

1551

+5.0

Single Mode (9)

LC

I(LN50)/1

S2G7C57LI

VLNC55

1571

+5.0

Single Mode (9)

LC

I(LN50)/1

S2G7C59LI

VLNC55

1591

+5.0

Single Mode (9)

LC

I(LN50)/1

S2G7C61LI

VLNC55

1611

+5.0

Single Mode (9)

LC

I(LN50)/1

S622C47EL

VLNC50

VLNC52

VLNC55

VLNC64

1471

+5.0

Single Mode (9)

LC

I(LN50)/1

S622C49EL

VLNC50

VLNC52

VLNC55

VLNC64

1491

+5.0

Single Mode (9)

LC

I(LN50)/1

S622C51EL

VLNC50

VLNC52

VLNC55

VLNC64

1511

+5.0

Single Mode (9)

LC

I(LN50)/1

S622C53EL

VLNC50

VLNC52

VLNC55

VLNC64

1531

+5.0

Single Mode (9)

LC

I(LN50)/1

S622C55EL

VLNC50

VLNC52

VLNC55

VLNC64

1551

+5.0

Single Mode (9)

LC

I(LN50)/1

S622C57EL

VLNC50

VLNC52

VLNC55

VLNC64

1571

+5.0

Single Mode (9)

LC

I(LN50)/1

S622C59EL

VLNC50

VLNC52

VLNC55

VLNC64

1591

+5.0

Single Mode (9)

LC

I(LN50)/1

S622C61EL

VLNC50

VLNC52

VLNC55

VLNC64

1611

+5.0

Single Mode (9)

LC

I(LN50)/1

SGEC47EL

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1471

+5.0

Single Mode (9)

LC

I(LN50)/1

SGEC49EL

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1491

+5.0

Single Mode (9)

LC

I(LN50)/1

SGEC51EL

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1511

+5.0

Single Mode (9)

LC

I(LN50)/1

SGEC53EL

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1531

+5.0

Single Mode (9)

LC

I(LN50)/1

SGEC55EL

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1551

+5.0

Single Mode (9)

LC

I(LN50)/1

SGEC57EL

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1571

+5.0

Single Mode (9)

LC

I(LN50)/1

SGEC59EL

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1591

+5.0

Single Mode (9)

LC

I(LN50)/1

SGEC61EL

VLNC40

VLNC42

VLNC42B

VLNC50

VLNC52

VLNC55

VLNC60

VLNC61

VLNC62

VLNC64

1611

+5.0

Single Mode (9)

LC

I(LN50)/1

General laser information

Optical fiber telecommunication systems, their associated test sets, and similar operating systems use semiconductor laser transmitters that emit infrared (IR) light at wavelengths between approximately 800 nanometers (nm) and 1600 nm. The emitted light is above the red end of the visible spectrum, which is normally not visible to the human eye. Although radiant energy at near-IR wavelengths is officially designated invisible, some people can see the shorter wavelength energy even at power levels several orders of magnitude below any that have been shown to cause injury to the eye.

Conventional lasers can produce an intense beam of monochromatic light. Monochromatic light is a single wavelength output of pure color that may be visible or invisible to the eye. A conventional laser produces a small-sized beam of light, and because the beam size is small, the power density (also called irradiance) is very high. Consequently, lasers and laser products are subject to federal and applicable state regulations as well as international standards for their safe operation.

A conventional laser beam expands very little over distance, or is said to be very well collimated. Thus, conventional laser irradiance remains relatively constant over distance. However, lasers used in lightwave systems have a large beam divergence, typically 10 to 20 degrees. Here, irradiance obeys the inverse square law (doubling the distance reduces the irradiance by a factor of four) and rapidly decreases over distance.

Lasers and eye damage

The optical energy emitted by laser and high-radiance LEDs in the 400 to 1400–nm range may cause eye damage if absorbed by the retina. When a beam of light enters the eye, the eye magnifies and focuses the energy on the retina magnifying the irradiance. The irradiance of the energy that reaches the retina is higher than at the cornea and, if sufficiently intense, may cause a retinal burn.

The damage mechanism at the wavelengths used in optical fiber telecommunications is thermal in origin; for example, damage caused by heating. Therefore, a specific amount of energy is required for a definite time to heat an area of retinal tissue. Damage to the retina occurs only when one looks at the light sufficiently long that the product of the retinal irradiance and the viewing time exceeds the damage threshold. Optical energies above 1400 nm cause corneal and skin burns, but these optical energies do not affect the retina. The thresholds for injury at wavelengths greater than 1400 nm are significantly higher than those for wavelengths in the retinal hazard region.

Classification of lasers

Manufacturers of lasers and laser products in the United States are regulated by the Food and Drug Administration's Center for Devices and Radiological Health (FDA/CDRH) under 21 CFR 1040. These regulations require manufacturers to certify each laser or laser product as belonging to one of the following classes: I, II, lla, IlIa, lllb, or IV.

The International Electrotechnical Commission (IEC) is an international standards body that writes laser safety standards under IEC-60825. Classification schemes are similar and divided into Classes 1, 1M, 2, 2M, 3B, 3R, and 4. Lasers are classified according to the accessible emission limits and their potential for causing injury.

Optical fiber telecommunication systems are generally classified as Class I/1, because, under normal operating conditions, all energized laser transmitting circuit packs are terminated on optical fibers which enclose the laser energy with the fiber sheath forming a protective housing. Also, a protective housing/access panel is typically installed in front of the laser circuit pack shelves. The circuit packs themselves, however, may be FDA/CDRH Class I, IIIb, or IV or IEC Class 1, 1M, 3B, 3R, or 4. State-of-the-art Raman and EDFA optical amplifiers have now extended into the Class IV/4 designations.

Laser safety precautions for optical fiber telecommunications systems

In its normal operating mode, an optical fiber telecommunication system is totally enclosed and presents no risk of eye injury. It is a Class I/1 system under the FDA/CDRH and IEC classifications.

The fiber optic cables that interconnect various components of an optical fiber telecommunication system can disconnect or break and may expose people to lightwave emission. Also, certain measurements and maintenance procedures may expose the technician to emission from the semiconductor laser during installation and servicing. Unlike more familiar laser devices, such as solid-state and gas lasers, the emission pattern of a semiconductor laser results in a highly divergent beam. In a divergent beam, the irradiance (power density) decreases rapidly with distance. The greater the distance, the less energy will enter the eye and the less potential risk for eye injury. If you inadvertently view an unterminated fiber or damaged fiber with the unaided eye at distances greater than 5 to 6 inches, normally, it will not cause eye injury provided that the power in the fiber is less than a few milliwatts at the near IR wavelengths and a few tens of milliwatts at the far IR wavelengths. However, damage may occur if you use an optical instrument such as a microscope, magnifying glass, or eye loupe to stare at the energized fiber end.

Laser radiation
CAUTION  DANGER 

CAUTION

Laser hazard

Use of controls or adjustments or performance of procedures other than those specified herein may result in hazardous laser radiation exposure.

Do not view directly into the laser beam with optical instruments such as a fiber microscope because viewing of laser emission in excess of Class 1 limits significantly increases the risk of eye damage.

Never look into the end of an exposed fiber or an open connector as long as the optical source is switched on.

Ensure that the optical source is switched off before disconnecting optical fiber connectors.

Laser safety precautions for enclosed systems

Under normal operating conditions, optical fiber telecommunication systems are completely enclosed. Observe the following laser safety precautions for enclosed systems:

Laser safety precautions for unenclosed systems

During service, maintenance, or restoration, an optical fiber telecommunication system is considered unenclosed. Observe the following laser safety precautions for unenclosed systems:

For guidance on the safe use of optical fiber optic communication systems in the workplace, consult ANSI Z136.2, American National Standard for Safe Use of Optical Fiber Communication Systems Utilizing Laser Diodes and LED Sources in the United States or outside the United States, IEC-60825, Part 2.

Laser warning labels

The following figure shows the different types of laser warning labels:

Figure 1-1: Laser warning labels
Laser warning labels

Legend

1. Laser symbol

2. Laser classification label (This label may show only the laser class or both the laser class and the maximum output power.)

3. Laser warning label

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