Quickly understand the difference of CWDM and DWDM technology

Some customers are asking for the difference of the CWDM and DWDM technology.

CWDM and DWDM both use the Wavelength Division Multiplexing (WDM) technology, but with different features. As shown in the below picture, there is a comparison between CWDM and DWDM technology. A CWDM MUX/DEMUX deals with small amounts of wavelengths, only up to 18 CWDM wavelength, but with large spans between wavelengths (spaced typically at around 20nm, from 1270 nm to 1610 nm). 

A DWDM MUX/DEMUX deals with narrower wavelength spans (no more than 0.8nm, 0.4nm or perhaps 0.2nm), and may accommodate 40,80, or even 160 wavelengths(mostly used is Channel 17 to Channel 61 wavelength).

HTFuture can provide you the full range of CWDM DWDM products that you need. If there is any inquiry, just let me know please. Ivy: sales6@htfuture.com

CWDM DWDM MUX DEMUX

What's the main raw materials for optical transceiver?

The main components of the product are optoelectronic devices(TOSA,ROSA,BOSA), shell (optical interface) and PCBA.
  
◆ TOSA(Transmitting Optical Sub-Assembly), with 4 PINS; ROSA(Receiving Optical Sub-Assembly), with 5 PINS; BOSA(Bi-Directional Optical Sub-Assembly), with 9 PINS.

◆ PCBA is a circuit board. Engineers will select the different chip design according to the projects. The common chips are SEMTECH, UXUN, Maxim and Macom.

◆ The optical module shell is generally divided into single and dual fiber. According to the interface type, mainly divided into LC and SC.

Different types of optoelectronic devices, the raw materials are not exactly the same, as follows:
TOSA: TO-CAN, ceramic cores, tube(Metal in general)
Classification of ceramic cores
※ Precision: single mode ceramic core and multimode ceramic core
※ outside diameter: SC(2.5mm) , LC(1.25mm)

Major chip manufacturers: 
Japan: Mitsubishi, Sumitomo
USA: CY（CYoptics）, AOI
Taiwan: LuxNet, Truelight

ROSA: PIN-TIA 、tube(Plastic in general)
PIN-TIA chip manufacturers:
Domestic: Fiberhome, Mignal, Opto Sensor Tech
Abroad: NT(Nanotech), Oclaro, SEMTECH etc.

BOSA: TO-CAN, ceramic cores, tube and filters

HTFuture aim to be your Reliable Partner for different kinds of Compatible transceiver (QSFP28, QSFP+, SFP, XFP, SFP+ etc) | OTN optical transmission system|DWDM Mux Demux|OADM | OTU | EDFA | NMS | DCM | OLP | OBP etc| More information, welcome to contact Ivy or skype: sales6@htfuture.com 

What's the difference between G652,G657A,G655 and G654 fiber?

Optical cables are made to meet the optical, mechanical or environmental performance specifications.It is a communication cable assembly that can be used individually or in group. Active Optical cable is the main transmission tool of various information network in the society.

Optical cable is consist of core, coating and jacket.
Core: Higher refractive index, for transmitting light;
Coating: Lower refractive index, form a total reflection condition with core;
Jacket: High strength, can bear greater impact, protect optical fiber.

Common optical fiber and differences:

G652: Standard single mode fiber, zero dispersion point is in 1300nm,divides into G652A,B,C,D.The main difference is PMD. It’s feature is that the fiber dispersion is very small when working wavelength is 1300nm, the transmission distance of the system is only limited by the loss;

G657A: Available in D, E, S, C and L5 wavebands. It can work in the whole working wavelength range of 1260-1625nm. With excellent bending performance and the technical requirements of geometric size are more accurate;

G655: Non zero dispersion-shifted fiber (NZ-DSF) contains 655A,B,C; The main characteristic is that the dispersion of 1550nm is close to zero, but not zero. It is an improved dispersion-shifted fiber to suppress four-wave mixing;

G654:Ultra low loss optical fiber, mainly used for transoceanic optical cable. The common core is pure SiO2,while the ordinary ones need to be doped with germanium. The loss near 1550nm is minimum, only 0.185dB/km, the dispersion is relatively large,a bout 17～20 ps/(nm·km), But the dispersion is zero in the 1300nm wavelength region.

We can see from above that their difference on fiber types, dispersion and loss .

HTFuture aim to be your Reliable Partner for different kinds of Compatible transceiver (QSFP28, QSFP+, SFP, XFP, SFP+ etc) | OTN optical transmission system|DWDM Mux Demux|OADM | OTU | EDFA | NMS | DCM | OLP | OBP etc| More information, welcome to contact Ivy or skype: sales6@htfuture.com 

6 Essential Steps For Selecting Optical Transceiver

With the rapid development of optical communication, there are more and more optical transceivers on the market. The users are not only consider the stability and reliability of the optical transceiver, but also the price and quality and whether to meet the requirements of the equipment and other aspects. However, many people can’t identify the quality of the optical transceiver is good or bad, so suffer losses.

HTFuture Technology Co., Ltd has the responsibility to maintain the benign development of the optical communication industry, also have the obligation to guide the customers choose the right product. Following will share 6 steps for selecting optical transceiver, don't worry about can not choose the suitable optical transceiver.

  

Step 1. Identify new optical transceiver and used optical transceiver.
※ The price of original optical transceiver is very expensive. Although the price of used optical transceiver is low, it will happen some issues after six months. The reason is unstable optical power and the decline in the optical sensitivity etc.
※ Use the Optical Power Meter to check the output power whether meet the specification. If the difference is too large, it maybe the used optical transceiver.


Step 2. Select the appropriate type of optical transceiver as required .
The types of optical connector: FC, SC, ST, LC, MU and MTRJ. The optical transceiver has a different interface, the most common is LC, then is SC, this needs to be determined according to the actual needs.

       

Step 3. See the compatibility between the optical transceiver and device.
Users should pay attention to: It will be indicated that the product can be used in what brand of equipment in the product description, should also confirm with the seller. In order to ensure that customers can buy the optical transceiver with good performance, HTFuture Technology Co., Ltd will conduct a variety of tests for all compatible optical transceivers before shipment, including Material testing, Product parameter testing, Distance testing, Switch testing and Aging testing, to guarantee its compatibility and operability.


Step 4. Consider the temperature adaptability of the optical transceiver.
The working environment of the optical transceiver is in the engine room or switch, and the change of temperature will affect the optical power and the sensitivity of the optical transceiver. The temperature range of the common optical transceiver is 0°C~70°C, while the industrial optical transceiver is -40°C~85°C. HTFuture Technology Co., Ltd will guarantee the the stability of the industrial products from the requirement of the hardware, Physical cooling and Temperature compensation software.



Step 5. Consider whether the parameters of the optical transceiver meet the requirements of the equipment.
The parameters of the optical transceiver that need to be considered are: Central wavelength, transmission distance and transmission rate, etc..
※ 850nm(MM, multi-mode, low cost but short transmission distance, generally can only transfer 500M);
※ 1310nm (SM, single-mode, large loss in transmission process but small dispersion, generally used for transmission within 40KM); 
※ 1550nm (SM, single-mode, small loss in transmission process but large dispersion, generally used for long distance transmission over 40KM, the most distant direct transmission is 120KM).

Step 6. Judging according to the service life of optical transceiver.
The used optical transceiver will appear different degrees of problems after using se more than six months, less than one year. It is best to choose a regular, quality control capacity of the manufacturers to cooperate when selecting the optical transceiver. So as not to cause huge economic losses to you and your company.

With these 6 essential Steps, like having a pair of piercing eye,is no longer difficult to find a suitable optical transceiver. HTFuture Technology Co., Ltd have been devoted to provide our customers optical transceivers with high performance. 

HTFuture aim to be your Reliable Partner for different kinds of Compatible transceiver (QSFP28, QSFP+, SFP, XFP, SFP+ etc) | OTN optical transmission system|DWDM Mux Demux|OADM | OTU | EDFA | NMS | DCM | OLP | OBP etc| More information, welcome to contact Ivy or skype: sales6@htfuture.com 

Tips on How to Use Optical Transceivers.

Optical transceiver consists of optoelectronic devices, functional circuits, and optical interfaces. The optoelectronic devices include transmit and receive parts. The transmitting part is: Inputting a certain bit rate of the electric signal is processed by an internal driver chip to drive a semiconductor laser (LD) or a light emitting diode (LED) to emit a corresponding rate of modulated optical signal, and an internal optical power automatic control circuit is provided therein. The output optical signal power remains stable. The receiving part is: After a certain code rate of the optical signal input transceiver is converted into an electrical signal by the light detecting diode. After the preamplifier outputs the corresponding rate of the electrical signal, the output signal is generally PECL level. At the same time, an alarm signal will be output after the input optical power is less than a certain value.

Today HTFuture will share with everyone some tips on using optical transceivers if you usually pay attention to the maintenance of the optical transceiver. Note that the following two points can help you reduce the loss of the optical transceiver and improve the performance of the optical transceiver.

Note One:
1. There are CMOS devices in this chip. Pay attention to prevent static electricity during transportation and use.
2. The device grounding should be good, reduce parasitic inductance.
3. As far as possible manual welding, if you need to paste, control the reflow temperature cannot exceed 205℃.
4. Do not lay copper below the optical transceiver to prevent the impedance from changing.
5. The antenna should be away from other circuits to prevent radiation efficiency becomes lower or affect the normal use of other circuits.
6. The transceiver should be placed as far away from other low-frequency circuits, digital circuits.
7. It is recommended to use magnetic beads for the isolation power of the transceiver.

Note Two:
1. Do not look directly into the optical transceiver that has been inserted into the device (whether it is a long-range or short-range optical transceiver) with naked eyes, and avoid eye burns.

2. When using a long-distance optical transceiver, the transmit optical power is generally greater than the overload optical power. Therefore, it is necessary to pay attention to the length of the optical fiber and ensure that the actual received optical power is less than the overload optical power. If the length of the optical fiber is short, use a long-range optical transceiver and use it with light attenuation. Be careful not to burn out the optical transceiver.

3. To better protect the optical transceiver from cleaning, it is recommended that you plug the dust plug when it is not in use. If the optical contact is not clean, it may affect the signal quality, it may also lead to link problems and error codes.

4. Rx/Tx, or arrow in and out directions is generally marked on the optical transceiver to facilitate identification of the transceiver. Tx at one end must be connected to Rx at the other end, otherwise the two ends cannot be linked.

Read the above notes, whether do you have a new understanding of the use of optical transceivers? It is important to be helpful to everyone and thank you for your support and attention to HTFuture. For more product details, please visit our official website.


HTFuture aim to be your Reliable Partner for different kinds of Compatible transceiver (QSFP28, QSFP+, SFP, XFP, SFP+ etc) | OTN optical transmission system|DWDM Mux Demux|OADM | OTU | EDFA | NMS | DCM | OLP | OBP etc| More information, welcome to contact Ivy or skype: sales6@htfuture.com 

How to distinguish between multimode and singlemode Transceiver?

These day some clients want to know about the difference between multimode and single mode Transceiver, so we summarize some information about multimode and single-mode.

The difference between single mode and multimode of optical modules of different manufacturers is not the same, but in general, single mode optical modules and multimode optical modules are clearly distinguished.

1. What is a single mode optical module and a multimode optical module?
The single-mode (SM) optical module has small limitations and is suitable for long-distance data transmission. The multi-mode (MM) optical module can transmit multiple modes of light and is suitable for short-distance transmission. The single mode and multimode in the optical module actually refer to the type of optical fiber connected to the optical module.

2. The difference between single mode optical module and multimode optical module

(1) different wavelengths
The operating wavelength of a multimode optical module is generally 850 nm, and the operating wavelength of a single mode optical module is generally 1310 nm and 1550 nm.

(2) Different transmission distances
Single-mode optical modules are often used for long-distance transmission with transmission distances of up to 150 to 200 km. Multimode optical modules are mostly used for short-distance transmission, and multi-mode optical modules can be used with transmission distances of less than 2 km.

(3) Different fiber types
According to the transmission mode of the optical module in the optical fiber, the optical fiber can be classified into a single mode fiber and a multimode fiber. Multimode fiber (MMF) fiber diameter is generally 50/125μm or 62.5/125μm, single mode fiber (SMF) fiber diameter is 9/125μm

(4) different light sources
The light source of the single mode optical module is an LD or a narrow spectral line LED, and the light source of the multimode optical module is a light emitting diode or a laser.

(5) Different application scope
Single-mode optical modules are often used in transmission lines with relatively high transmission distances, such as metropolitan area networks.
Multi-mode optical modules are mostly used for short-distance transmission, and the transmission of network nodes and connectors is also very suitable for multi-mode optical modules.
In addition, multimode devices can only operate efficiently on multimode fibers, while singlemode devices can operate on both single-mode and multimode fibers, but single-mode devices do not guarantee results on multimode fibers.

(6) Different prices
Although single-mode fiber is cheaper than multimode fiber, single-mode optical modules are much higher than multimode optical modules.

3. Precautions for using single mode optical modules and multimode optical modules
(1) When using a single-mode optical module, ensure that the actual received optical power is less than the overload optical power, so the optical power is measured in combination with the optical power, and then selectively used with the optical attenuator.
(2) When using a single-mode optical module, there is a margin for receiving power.
(3) Multimode optical modules can only transmit signals of one wavelength and cannot be used with multiplexers.
(4) Multimode optical modules are limited to running on multimode fiber

HTFuture aim to be your Reliable Partner for different kinds of Compatible transceiver (QSFP28, QSFP+, SFP, XFP, SFP+ etc) | OTN optical transmission system | DWDM Mux Demux | OADM | OTU | EDFA | NMS | DCM | OLP | OBP etc |  More information, welcome to contact Ivy or skype: sales6@htfuture.com 

Do you know the Difference Between FP And DFB Laser?

FP laser
FP (Fabry-perot) laser is mainly used for low data rate short-distance transmission, the transmission distance is generally within 20 km,the rate is generally within 1.25G. FP is divided into two wavelengths, 1310nm/1550nm.
Some customer in order to decrease the cost , so chose the FP laser to make the 1.25G 40km module. Reason by make the module reach the 40km transmission distance,  the engineer must adjust the output power rather bigger to meet the distance, but it will make the laser ageing fastly cause more issue.

The performance parameters of FP laser:
1）Working wavelength: Emitted the center wavelength of spectrum by laser.
2）The width of spectral: RMS spectral width of multi-longitudinal mode laser.
3）Threshold current: The laser send out a very good laser when the working current of the device exceeds the threshold current.
4）Output power: The optical power emitted by the output port of the laser.

The typical parameters are shown in the following table:

DFB laser
DFB ( Distributed Feedback Laser) laser use the grating filter device to make the device have only one longitudinal-mode output based on the FP laser.DFB generally also use two wavelengths 1310nm and 1550nm, divides into refrigeration and No-refrigeration, mainly used for high data rate  long-distance transmission.The transmission distance is generally above 40 kilometers, the rate is above 1.25G.

The performance parameters of DFB laser:
1）Working wavelength: Emitted the center wavelength of spectrum by laser.
2）The suppression ratio of side mode: The power ratio of the main mode and the maximum side mode of the laser.
3）Decreased the spectral width of 20dB: Decreased the spectral width of 20dB by the highest point of the laser output spectrum.
4）Threshold current: The laser send out a very good laser when the working current of the device exceeds the threshold current.
5）Output power: The optical power emitted by the output port of the laser.

The typical parameters are shown in the following table:

The main difference can be got by the form between the FP and DFB laser is that the spectral width is different. The spectral width of the DFB laser is generally narrow, is a single longitudinal mode with distributed negative feedback. While the spectral width of the FP laser is relatively wide, it is a multi-longitudinal mode laser. The working wavelength, threshold current and voltage are also different.

HTFuture aim to be your Reliable Partner for different kinds of Compatible transceiver   |  OTN optical transmission system  |  DWDM Mux Demux  |  OADM I OTU I EDFA I NMS  |  DCM    |   OLP  |  OBP |      More information, welcome to contact Ivy or skype: sales6@htfuture.com 

How To Chose Good Quality Optical Transceiver?

With the development of optical telecom market, more and more customers begin to pay attention to the stability and reliability of the optical transceiver . There are three kinds of optical transceivers on the market now:

* Original optical transceiver 
* Second-hand optical transceiver 
* Compatible optical transceiver

As we know, the price of the original optical transceiver is rather expensive, many manufacturers can only be discouraged. 

As for second-hand optical transceiver, although it’s price is relatively low, the quality can’t be guaranteed. It often will be abnormal after six months in use.

Therefore,many manufacturers have turned their attention to the compatible optical transceiver. Indeed,the performance of compatible optical transceiver is almost the same as the original optical transceiver. While the price is several times cheaper than the original optical transceiver.This is also why the compatible optical transceiver are so popular Currently .However, the quality of goods is not easy to identify, so the customer got some bad one , it hurt the customer deeply. In order to protect the benifits of the customers and friends, Here Shenzhen HTFuture Co. Ltd. will share with you some details about the way of selecting optical transceiver.

The first question,how do we distinguish between new optical transceiver and used optical transceiver?

Second-hand optical transceiver will happen some issues after six months or one year. The reason is unstable optical power and the decline in the optical sensitivity and other matters. If you have the Optical Power Meter, you can check the output power whether meet the specification. If the difference is too large, it maybe chose the second-hand optical transceiver.

Then observe the working status after selling. The service life of a normal optical transceiver is 5 years,it is very difficult to see the optical transceiver is good or bad in the first year,but it can be seen out in the second or third year of use. 

And then see the compatibility between the optical transceiver and device.Customers need to communicate with the suppliers before the purchase,tell them need to use the device on which brand. In order to ensure that customers can buy the optical transceiver with good performance, Shenzhen HTFuture Co. Ltd. will conduct a variety of tests for all compatible optical transceivers before shipment, including Material testing, Product parameter testing, Distance testing, Switch compatible testing and Burn-in testing, it will be good for guaranting its compatibility and operability.

Finally,we also need to see the temperature adaptability of the optical transceiver. When the module working will cause a little heat, but not so hot. Its general working environment is in the date center or on the switch. The temperature is too high or too low will affect its optical power, optical sensitivity and other parameters. Generally the temperature range of optical transceiver is at 0~70°C. If extremely cold or hot environment, we need to use the industrial optical transceiver at -40~85°C. Shenzhen HTFuture Co. Ltd. will guarantee the the stability of the industrial products from the requirement of the hardware, Physical cooling and Temperature compensation software.



The installation of optical transceiver:

If you found that the function of optical transceiver is invalid in the processing, don’t worry, be careful inspection and analysis the specific reasons.

There are two main types of failure of the optical transceiver, transmitting end failure and receiving end failure. The most common reasons are the following aspects:

1)The optical transceiver port exposed in the air, dust cover the insection and pollution;
2)The section of optical connector has been contaminated, then cause the optical transceiver port is secondary pollution;
3)The section of pigtail operate improper bring scratched etc;
4)The bad optical connector will lead to problem too.

Therefore,after the proper selection of optical transceiver,you also need to pay attention to the cleaning and protection in all of the processing. After the installation, put the dust cap when there is stop working. Because if the optical port is not cleanning, it is possible to affect the quality of the signal, and may lead to link problems and error problems.

Shenzhen HTFuture Co. Ltd. have been devoted to provide our customers optical transceivers with high performance.Hope our customers will be satisfied with our products and service. 

Some knowledge in the data center 100G optical module. And Do you know how to choose 100G optical module?

The traditional data center is mainly based on the 10G network architecture. In order to adapt to the scale deployment of AI, deep learning, big data computing and other services, the next-generation data center architecture is evolving to the 25G/100G network architecture. 

Building a 25G/100G data center requires a large number of 100G optical modules, which account for a relatively high proportion of network construction costs. What are the 100G optical module standards? How do we choose? Today, we will briefly review the data center 100G optical module standards and package formats.

100G optical module standard organization

Before you begin to share the optical module standards, first understand the standardization organization of the lower optical module. The definition of optical modules is mainly two key organizations, namely IEEE and MSA (Multi Source Agreement), which complement each other and learn from each other.

Everyone knows that IEEE is the Institute of Electrical and Electronics Engineers, and 802.3 is a working group under IEEE. Many 10G, 40G, 100G, and 400G optical module standards are proposed by the IEEE 802.3 working group.

MSA is a multi-vendor specification. Compared with IEEE, it is a non-official organization. It will form different MSA protocols for different optical module standards. It can be understood as the behavior of enterprise alliances within the industry. In addition to defining the structural package of the optical module (including external dimensions, electrical connectors, pin assignments, etc.), the MSA also defines electrical and optical interfaces to form a complete optical module standard.

A long time ago, the optical module industry chain was very chaotic. Each manufacturer had its own structural package. The developed optical modules were large and small, and the interfaces were varied. In order to solve this problem, the MSA multi-source protocol came into being. Each manufacturer follows the standard package of the unified optical module proposed by MSA and the related interface, which is like the standardization of the charging port of the mobile phone. For 100G, MSA defined standards include 100G PSM4 MSA, 100G CWDM4 MSA, and 100G Lambda MSA.

100G optical module standard

In order to meet 100G interconnection scenarios of different distances, IEEE and MSA define more than ten 100G standards, but the mainstream is the following six standards.

▲100G optical module mainstream standard

The standard beginning with 100GBASE is proposed by IEEE 802.3.

As shown in FIG:

In the 100GBASE-LR4 name, LR means long reach, that is, 10Km, and 4 means four channels, that is, 4*25G, which are combined to be a 100G optical module capable of transmitting 10Km.

The naming rules for -R are as follows:

▲-R noun explanation

In addition to the IEEE 100GBASE series of standards, why does MSA also propose the PSM4 and CWDM4 standards?

100GBASE-SR4 and 100GBASE-LR4 are the most commonly used 100G interface specifications defined by the IEEE. However, for large data center internal interconnection scenarios, the distance supported by 100GBASE-SR4 is too short to meet all interconnection requirements, and the cost of 100GBASE-LR4 is too high. As a result, MSA brought a solution for mid-range connectivity to the market, and PSM4 and CWDM4 were the products of this revolution.

Of course, the capability of 100GBASE-LR4 completely covers CWDM4, but in the scenario of 2Km transmission, the CWDM4 solution is cheaper and more competitive.

The following figure is a schematic diagram of 100GBASE-LR4 and 100G CWDM4:

▲ 100GBASE-LR4 schematic

▲100G CWDM4 schematic

LR4 and CWDM4 are similar in principle, and the four parallel 25G channels are wavelength-multiplexed into a 100G fiber link through the optical device MUX and DEMUX. However, there are several differences between the two:

1. Optical MUX/DEMUX devices used by LR4 are more expensive

CWDM4 defines a CWDM interval of 20 nm, because the wavelength drift characteristic of the laser is about 0.08 nm/°C, and the wavelength variation in the 0~70 °C operating range is about 5.6 nm, and the channel itself also leaves some isolation bands.

Channel 1: 1264.5~1277.5nm

Channel 2: 1284.5~1297.5nm

Channel three: 1304.5~1317.5nm

Channel 4: 1324.5~1337.5nm

LR4 defines a LAN-WDM interval of 4.5 nm.

Channel 1: 1294.53~1296.59nm

Channel 2: 1129.02~1301.09nm

Channel three: 1303.54~1305.63nm

Channel four: 1308.09~1310.19nm

The larger the channel spacing, the lower the requirements for optical MUX/DEMUX devices and the cost savings.

2. The laser used in LR4 is more expensive and consumes more power.

CWDM4 uses DML (Direct Modulated Laser), while LR4 uses EML (Electro-absorption Modulated Laser).

DML is a single laser, and EML is two devices, one is DML and the other is EAM modulator, together called EML. The principle of DML is to realize the signal modulation by modulating the injection current of the laser. Since the magnitude of the injection current changes the refractive index of the active region of the laser, causing wavelength drift to generate dispersion, it is difficult to make high-speed signal modulation. Not far enough. 10KM is a little powerless for DML, only on EML.

Note: Chirp refers to a signal whose frequency changes (increases or decreases) over time. This signal sounds like a beeping sound of a bird.

3. LR4 requires an additional TEC (Thermo Electric Cooler)

Because there is only a 4.5 nm spacing between adjacent channels of LR4, the laser needs to be placed on the TEC for temperature control. The TEC Driver chip needs to be placed on the circuit, and the Laser is also integrated into the TEC material. As a result, the cost of the LR4 is increased compared to the CWDM4.

Based on the above three points, the optical module of the 100GBASE-LR4 standard is more expensive, so the 100G CWDM4 standard proposed by MSA is a good complement to the gap caused by the excessive cost of 100GBASE-LR4 within 2Km.

In addition to CWDM4, PSM4 is also a medium-distance transmission scheme. What are the advantages and disadvantages of PSM4 compared to CWDM4?

The 100G PSM4 specification defines eight single-mode fiber (4 transmit and 4 receive) point-to-point 100 Gbps links, each transmitted at 25 Gbps. Four channels of the same wavelength and independent are used for each signal direction. Therefore, the two transceivers typically communicate via an 8-fiber MTP / MPO single mode jumper. The PSM4 has a transmission distance of up to 500 meters.

▲PSM4 schematic

▲CWDM4 vs PSM4

After talking about the 100G long-distance optical module standard, look at the 100G short-range optical module.

The 100G short-range optical module standards mainly include 100GBASE-SR10 and 100GBASE-SR4. In order to meet the 100G demand appearing on the market, the 100GBASE-SR10 standard was first proposed and applied to the short-distance interconnection of 100G.

The 100GBASE-SR10 standard uses 10 x 10Gbps parallel channels for 100Gbps point-to-point transmission. The rate of electrical signals is 10G, and the optical signal rate is also 10G. It uses NRZ modulation and 64B/66B encoding. Because IEEE 802.3 proposed the 100GBASE-SR10 standard as early as 2010, the application specific integrated circuit (IC) can only support 10G, which is CAUI-10 (10 channels x 10Gbps).

▲100GBASE-SR10 schematic

As the switch ASIC chip electrical interface rate is increased from 10Gpbs to 25G bps, the electrical interface standard is upgraded from CAUI-10 (10 channels x 10Gbps) to CAUI-4 (4 channels x 25Gbps), and the channel is reduced from parallel 10 channels of SR10 to parallel With 4 channels, the number of devices in the optical module is reduced, the cost is reduced, the module size is reduced, and power consumption is reduced.

The reduction of the size of the optical module makes the density of the 100G interface provided by the switch per 1U space larger. Based on the above advantages, 100GBASE-SR4 has replaced the 100GBASE-SR10 as the mainstream standard of 100G short-range optical modules.

▲100GBASE-SR4 schematic

100G optical module package

Only the optical interface and electrical interface specifications of the optical module are not enough, and the required structural package is required to be a complete optical module solution. The package formats of 100G optical modules mainly include CFP, CFP2, CFP4, and QSFP28.

CFP was first proposed, short-distance transmission application 100GBASE-SR10 standard, long-distance transmission application 100GBASE-LR4. The first-generation CFP long-distance transmission scheme is as follows. Since the electrical interface capability is only CAUI-10, the built-in Gearbox (10:4 Serializer in the figure below) is required to convert 10 x 10 Gbps and 4 x 25 Gbps electrical signals. Later, as the electrical signal was upgraded to CAUI-4, the second generation CFP (CFP2/CFP4) long-distance transmission scheme did not require the built-in Gearbox.

▲ first generation CFP optical module long distance solution

However, the CFP size is too large. As the integration of optical modules is getting higher and higher, the later development direction is to make the size smaller and the power consumption lower. CFP can be evolved to CFP2, CFP4, and then QSFP28 appears later. . Compared to the CFP4, the QSFP28 is smaller in size and lower in power consumption. The smaller size of the QSFP28 allows the switch to have a higher port density (typically 36 Gigabit interfaces can be deployed per board). Currently, QSFP28 is the mainstream package format for 100G optical modules in the data center.

▲CFP/CFP2/CFP4/QSFP28 optical module size comparison

Finally, to summarize, how to choose the internal interconnect optical module of 25G/100G data center, I suggest you refer to the following standards:

100G short-range interconnection scene (TOR-LEAF) not exceeding 100 meters, using 100GBASE-SR4 QSFP28 optical module;

100G mid-range interconnection scene (LEAF-SPINE) from 100 meters to 500 meters, using 100G PSM4 QSFP28 optical module;

100G medium long distance interconnection scene (LEAF-SPINE, SPINE-CORE) of 500 meters to 2Km, using 100G CWDM4 QSFP28 optical module;

Long-distance interconnection scenario (CORE-MAN) over 2Km, using 100GBASE-LR4 QSFP28 optical module.

Finally, the explanation of the terminology is attached.

If you would like more information of 100G Transceiver, please contact Ivy by email or skype: sales6@htfuture.com 

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(3) Optical Transport Network Product (OEO, OTU, OBP, OLP, EDFA etc)