KR20200078297A - Active Optical Cable - Google Patents

Abstract

Disclosed is an active optical cable (AOC). The embodiment provides the AOC, which creates, changes, deletes and transmits new information necessary for network equipment to recognize and operate the active optical cable itself, when the AOC is connected with the network equipment, and allows to smoothly perform data communication without obstacles in a data center equipped with the network equipment.

Description

Active Optical Cable

This embodiment relates to an active optical cable.

The contents described below merely provide background information related to the present embodiment, and do not constitute a prior art.

The Cisco Visual Networking Index 2018 will reach 85 GB per month of Internet data usage per person in 2022, and network connection devices per capita thanks to advances in Internet of Things (IoT), 5G mobile communication network technology, etc. The number of predicted is over 3.6. In addition, it was estimated that the share of video in total data traffic will exceed 80% in 2022 from 70% in 2017.

When explosively increasing data traffic is classified by destination, it can be divided into data centers, data centers and data centers, and between data centers and users. More than 70% of global data traffic occurs inside data centers. do. In other words, the vast majority of data originating from around the world is due to the production, processing, storage, and authentication of data originating from within the data center.

The Optical Interconnect Solution is the most realistic solution to the growing data traffic in this explosively growing data center.

Optical connectivity solutions have already replaced copper-based networks in long-distance and metropolitan communication networks, and are expanding the field thanks to increased bandwidth and advances in optical communication technology. Among these optical connection solutions, one of the representative forms of providing a long-distance optical connection solution is an optical transceiver.

From the user's point of view, the optical transceiver has both an electrical interface and an optical interface at the same time. When two devices are to be connected using an optical transmitter and receiver, a patch cord connecting the two optical transmitters and the two optical transmitters is required, and the characteristics of the optical signals transmitted and received by the two optical transmitters and receivers It must be designed and manufactured to fit. That is, when a user selects a patch cord that connects between two optical transmitters and optical transmitters, the performance and standard interface of the two optical transmitters must be carefully selected and selected. For example, if one optical transmitter adopts a light source for a multi-mode optical fiber, the optical receiver on the other side must also be an optical transmitter using a light source for a multi-mode optical fiber, and a patch connecting the two optical transmitters The cord should be based on a multimode fiber. That is, the optical transmitter and receiver having both an electrical interface and an optical interface are difficult to maintain and manage, and have less freedom of selection than an active optical cable having only an electrical interface.

SFP (Small Form Factor Pluggable) type active optical cable shown in FIG. 1(a) structurally similar to the optical transmitter or receiver, or QSFP (Quad Small Form Factor Pluggable) type active type shown in FIG. 1(b). Optical cables have only an electrical interface. Since the optical transmission/reception module at both ends of the SFP active optical cable or the QSFP active optical cable can be tested and set up during the manufacturing process, it is not always necessary to monitor the light output of the light source as in the conventional optical transmission and reception. That is, in the case of an active optical cable having such a structure, the performance and function are the same as the optical transmitter and receiver, while installation, maintenance and management are relatively easy.

Therefore, there is a need for an active optical cable that is easy to install and use, has a simple maintenance and management, and has at least the performance of an optical transmitter and receiver, like a conventional copper cable.

In this embodiment, when an active optical cable (AOC) is connected to network equipment, the active optical cable generates, changes, and deletes new information necessary for the network equipment to recognize and operate the active optical cable itself, and then transmits the network. It is an object of the present invention to provide an active optical cable that enables data to be smoothly and smoothly communicated without obstacles in a data center equipped with equipment.

According to an aspect of the present embodiment, an optical link for transmitting an optical signal input from outside of the first end and the second end in both directions including a first end and a second end; Convert the first electrical signal input from the outside into a first optical signal and transmit to the other side of the optical link using the first end or a second optical signal received from the opposite side of the optical link using the at least one optical link Is converted to a second electrical signal and output to the outside, the first optical signal is controlled by using the first information, which is at least one of pre-stored electrical and optical characteristics, temperature characteristics, and unique characteristic information, and the first A first transmission/reception module for generating, changing or deleting information; The third optical signal input from the outside is converted into a third optical signal and transmitted to the first transmission/reception module using the second end or a fourth optical signal received from the first transmission/reception module using the second end Is converted to a fourth electrical signal and output to the outside, the third optical signal is controlled using the second information, which is at least one of pre-stored electrical and optical characteristics, temperature characteristics, and unique characteristic information, and the second It provides an active optical cable characterized in that it comprises a second transmission and reception module for generating, changing or deleting information.

As described above, according to the present embodiment, when an active optical cable (AOC) is connected to a network equipment, the active optical cable generates and changes new information necessary for the network equipment to recognize and operate the active optical cable itself, There is an effect of smoothly and smoothly performing data communication without an obstacle in the data center equipped with network equipment by transmitting after deletion.

1 is a view showing a typical active optical cable.
2 is a view showing an application example of an active optical cable according to the present embodiment.
3 is a block diagram schematically showing an internal module of an active optical cable (AOC) according to the first embodiment.
4 is a block diagram schematically showing an internal module of an active optical cable (AOC) according to a second embodiment.
5 is a diagram showing information stored in an internal storage in an active optical cable (AOC) according to the present embodiment.
6 is a view showing the concept of an optical system included in the light transmission and reception assembly according to this embodiment.

Hereinafter, this embodiment will be described in detail with reference to the accompanying drawings.

2 is a view showing an application example of an active optical cable according to the present embodiment.

The active optical cable 200 according to the present embodiment is formed by including two transmission/reception modules and an optical link connecting the two transmission/reception modules. The components included in the active optical cable 200 are not necessarily limited thereto.

Referring to (a) of FIG. 2, the active optical cable 200 according to the present embodiment connects between the first host unit 202 and the second host unit 204 to transmit data from the first host unit 202. To the second host unit 204 and data from the second host unit 204 to the first host unit 202. The first host unit 202 and the second host unit 204 may be one selected from a network device that functions as a server, a switch, and storage.

Referring to (b) of FIG. 2, the active optical cable 200 according to the present embodiment is disposed as the first AOC connecting the first host unit 202 and the second host unit 204, or the first host A plurality of host units included in the unit 202 may be arranged as a second AOC connecting the two selected host units among the 1A host unit, the 1B host unit, and the 1C host unit, or the second host unit 204 ) May be arranged to connect between the 2A host part, the 2B host part, and the 2C host part, which are a plurality of host parts. Further, the active optical cable 200 may be an optical cable formed to connect a plurality of host parts from one host part. Individual host parts included in the first host part 202 and the second host part 204, that is, the 1A host part, the 1B host part and the 1C host part, the 2A host part, the 2B host part, and the 2C host Each of the parts may be one of a network device that functions as a switch, a server, and storage.

The Small Form-Factor (SFF) Multi-Source Agreement (MSA) defines a 256-byte Memory Map written to non-volatile memory. Here, the nonvolatile memory may be an electrically erasable and programmable read-only memory (EEPROM).

In the EEPROM memory map, information of the performance of the optical transmission/reception module, a standard interface, and a manufacturer may be recorded. Includes an I²C interface to provide communication with external devices. These interfaces can be configured to support communication with external devices using a single wire or multiple wires. for example, The EEPROM memory map can use an 8-bit address 1010000X (A0h).

The latest optical transmission/reception module supports standard digital diagnostic monitoring (DDM) function. The standard digital diagnostic monitoring function is also called Digital Optical Monitoring (DOM). The user of the optical transmission/reception module can monitor various optical transmission/reception module parameters of the optical transmission/reception module in real time using standard digital diagnostic monitoring (DDM) and digital optical monitoring (DOM).

Various parameters of optical transmission module of optical transmission module include type of optical transmission module, connector type, electronic and/or optical compatibility, code for High Speed Serial Encoding Algorithm, Nominal Signaling Rate, Type of transmission rate selection function, link length, type of optical fiber supported, supplier name, IEEE company ID, serial number of product provided by supplier, manufacturer's manufacturing date code, part number provided by supplier, supplier Revision history of part numbers provided by, laser wavelength, optical output power, optical input power, temperature, laser bias current and module supply voltage It may include.

For example, DDM information can be used without changing the contents of 8-bit address 1010000X (A0h) using EEPROM information by making 8-bit address 1010001X (A2h) available. The upper 128 bytes of the A2h memory area are provided for future use.

Typically, standard digital diagnostic monitoring (DDM) and digital optical monitoring (DOM) functions are implemented for monitoring in routers, switches, and optical transmission equipment using Simple Network Management Protocol (SNMP).

The standard digital diagnostic monitoring (DDM) and digital optical monitoring (DOM) functions can display diagnostic data, alarms or warnings for the optical transmission/reception module using a DDM interface. In general, suppliers of optical transmission/reception modules can set thresholds for determining alarm criteria for various information. For example, a supplier of an optical transmission/reception module may set a threshold value that triggers a high alarm, a low alarm, a high alarm, or a low alarm before shipment and input it to the optical transmission and reception module.

Additionally, the DDM memory area has threshold information for laser temperature and TEC current (Thermo-Electric Cooler) alarms and warnings, diagnostic calibration constant information, CDR (Clock Data Recovery) status information, and reception judgment threshold information. Can be entered. Most modern optical transmission and reception module devices support DDM and/or DOM interfaces.

3 is a block diagram schematically showing an internal module of an active optical cable (AOC) according to the first embodiment.

The low power consumption active optical cable 200 according to the first embodiment includes a first transmission/reception module 310, a second transmission/reception module 320, and an optical link 330.

The optical link 330 includes a first end and a second end. The optical link 330 transmits optical signals input from outside of the first end and the second end in both directions.

The first transmission/reception module 310 includes a first electric pad unit 402, a first transmission unit 420, a first control unit 442, and a first reception unit 430. The first transmission/reception module 310 converts the first electrical signal input from the first host unit 202 into a first optical signal, and uses the first end of the optical link 330 to be the other side of the optical link 330. 2 Send to the end. The first transmission/reception module 310 converts the second optical signal received from the second end of the optical link 330 into a second electrical signal by using at least one optical link 330, and thus the first host unit 202. Output as The first transmission/reception module 310 controls the first optical signal using pre-stored first information (at least one of electrical/optical characteristics, temperature characteristics, and unique characteristic information).

The second transmission/reception module 320 includes a second electric pad unit 404, a second transmission unit 470, a second control unit 482, and a second reception unit 460. The second transmission/reception module 320 converts the third electrical signal input from the second host unit 204 into a third optical signal to the first transmission/reception module 310 using the second end of the optical link 330. Send. The second transmission/reception module 320 converts the fourth optical signal received from the first transmission/reception module to a fourth electrical signal by using the second end of the optical link 330 and outputs it to the second host unit 204. The second transmission/reception module 320 controls the third optical signal by using pre-stored second information (at least one of electrical/optical characteristics, temperature characteristics, and unique characteristic information).

4 is a block diagram schematically showing an internal module of an active optical cable (AOC) according to a second embodiment.

The low power consumption active optical cable 200 according to the second embodiment includes a first transmission/reception module 310, an optical link 330, and a second transmission/reception module 320.

The first transmission/reception module 310 includes a first electric pad unit 402, a first transmission unit 420, a first control unit 442, a first information management unit 446, and a first reception unit 430. The first transmission/reception module 310 converts the first electrical signal input from the first host unit 202 into a first optical signal, and uses the first end of the optical link 330 to be the other side of the optical link 330. 2 Send to the end. The first transmission/reception module 310 converts the second optical signal received from the second end of the optical link 330 into a second electrical signal by using at least one optical link 330, and thus the first host unit 202. Output as The first transmission/reception module 310 controls the first optical signal using pre-stored first information (at least one of electrical/optical characteristics, temperature characteristics, and unique characteristic information).

The first transmit/receive module 310 performs an initialization operation with an external first host unit 202 for a predetermined time before transmitting the first optical signal to the second transmit/receive module 320. The first transmission/reception module 310 includes at least one retimer and at least one equalizer.

The first electric pad unit 402 transmits and receives electric signals to and from the external first host unit 202.

The first transmitter 420 includes at least one first electro-optical conversion element that converts the first electrical signal into a first optical signal, and a first transmission circuit that drives the first electro-optical conversion element.

The first control unit 442 controls operations of the first transmission unit 420 and the first reception unit 430. The first control unit 442 controls the first transmission circuit so that the intensity of the optical signal generated by the at least one first all-optical conversion element is maintained even when the temperature of the inside and outside of the first transmission/reception module 310 changes. do.

The first control unit 442 causes the first information management unit 446 to generate fifth information that updates the third information based on the module parameter information previously stored in the first nonvolatile memory according to the result of the initialization operation.

Module parameter information includes nominal signaling rate, type of transmission rate selection function, link length, type of optical fiber supported, supplier name, IEEE company ID, serial number of product provided by supplier, supplier Manufacturing date code, part number provided by supplier, revision history of part number provided by supplier, laser wavelength, optical output power, optical input power, temperature, laser bias current ( Laser Bias Current) and module supply voltage (Module Supply Voltage).

The first information management unit 446 includes a first non-volatile memory. The first nonvolatile memory may be electrically erased and programmable read-only memory (EEPROM: Electrically Erasable Programmable Read-Only Memory). The first non-volatile memory stores first information (at least one of electrical and optical characteristics, temperature characteristics, and characteristic characteristics information).

The first information management unit 446 generates, changes, or deletes first information stored in the first nonvolatile memory. The first information management unit 446 generates, alters, or deletes at least one of the type of the first transmission/reception module 310 and the type of the first electric pad unit 402 to obtain first information (electrical/optical characteristics, temperature characteristics, and Third information is generated by updating at least one of the unique characteristic information).

The first control unit 442 is integrally formed with the first information management unit 446. The first information management unit 446 is formed integrally with the first nonvolatile memory.

The first receiver 430 includes at least one first photoelectric conversion element that converts the second optical signal into a second electrical signal, and a first reception circuit that drives the first photoelectric conversion element.

At least one first photoelectric conversion element included in the first transmitting unit 420 and at least one first photoelectric conversion element included in the first receiving unit 430 are optically connected to the optical link 330 using the first optical assembly. Leads to

The first optical assembly includes a first lens that processes light emitted from the first electro-optical conversion element as a first parallel beam of a parallel shape, and changes a traveling direction of the first parallel beam by a predetermined angle to a second parallel beam. It is formed integrally with a first mirror that forms a second lens that converges the second parallel beam and enters the first end located at a predetermined distance.

The second transmission/reception module 320 includes a second electric pad unit 404, a second transmission unit 470, a second control unit 482, a second information management unit 486, and a second reception unit 460. The second transmission/reception module 320 converts the third electrical signal input from the second host unit 204 into a third optical signal to the first transmission/reception module 310 using the second end of the optical link 330. Send. The second transmission/reception module 320 converts the fourth optical signal received from the first transmission/reception module to a fourth electrical signal by using the second end of the optical link 330 and outputs it to the second host unit 204. The second transmit/receive module 320 controls the third optical signal using the pre-stored second information (at least one of electrical/optical characteristics, temperature characteristics, and unique characteristic information).

The second transmission/reception module 320 performs an initialization operation with an external second host unit 204 for a predetermined time before transmitting the third optical signal to the first transmission/reception module 310. The second transmission/reception module 320 includes at least one retimer and at least one equalizer.

The second electric pad unit 404 transmits and receives electrical signals to and from the external second host unit 204.

The second transmitter 470 includes at least one second electro-optical conversion element that converts the third electrical signal into a third optical signal, and a second transmission circuit that drives the second electro-optical conversion element.

The second control unit 482 controls the operation of the second transmitting unit 470 and the second receiving unit 460. The second control unit 482 controls the second transmission circuit so that the intensity of the optical signal generated by the at least one second all-optical conversion element is kept constant even when the temperature of the inside and outside of the second transmission/reception module 320 changes. do.

The second control unit 482 causes the second information management unit 486 to generate sixth information that updates the fourth information based on the module parameter information previously stored in the second nonvolatile memory according to the result of the initialization operation.

Module parameter information includes nominal signaling rate, type of transmission rate selection function, link length, type of optical fiber supported, supplier name, IEEE company ID, serial number of product provided by supplier, supplier Manufacturing date code, part number provided by supplier, revision history of part number provided by supplier, laser wavelength, optical output power, optical input power, temperature, laser bias current ( Laser Bias Current) and module supply voltage (Module Supply Voltage).

The second information management unit 486 includes a second non-volatile memory. The second non-volatile memory may be electrically erased and programmable read only memory (EEPROM). The second nonvolatile memory stores second information.

The second information management unit 486 generates, changes, or deletes second information stored in the second nonvolatile memory. The second information management unit 486 generates the fourth information by updating the second information by creating, changing, or deleting at least one of the type of the second transmission/reception module 320 and the type of the second electric pad unit 404. .

The second control unit 482 is integrally formed with the second information management unit 486. The second information management unit is integrally formed with the second non-volatile memory.

The second receiver 460 includes at least one second photoelectric conversion element that converts the fourth optical signal into a fourth electrical signal, and a second reception circuit that drives the second photoelectric conversion element.

At least one second photoelectric conversion element included in the second transmission unit 470 and at least one second photoelectric conversion element included in the second reception unit 460 are optically connected to the optical link 330 using the second optical assembly. Leads to

The second optical assembly is a third lens that processes light emitted from the second electro-optical conversion element while spreading into a third parallel beam of a parallel shape, and changes a traveling direction of the third parallel beam by a predetermined angle to the fourth parallel beam. It is formed integrally with a second mirror constituting a fourth lens that converges the fourth parallel beam and enters the second end located at a predetermined distance.

The first optical signal, the second optical signal, the third optical signal, and the fourth optical signal are based on a pulse amplitude modulation technique using logical information values of at least two bits per unit clock pulse. It means the generated optical signal. Here, the pulse amplitude modulation technique includes PAM-4, PAM-8 and PAM-16.

The optical link 330 includes a first end and a second end. The optical link 330 transmits optical signals input from outside of the first end and the second end in both directions.

The optical link 330 includes at least one optical fiber. One end of at least one optical fiber in the optical link 330 is connected to the first transmission unit 420. The other end of the at least one optical fiber in the optical link 330 is connected to the second receiver 460.

5 is a diagram showing information stored in an internal storage in an active optical cable (AOC) according to the present embodiment.

As shown in FIG. 5, the serial ID, vendor specifications, and the like are stored in the internal storage of the first information management unit 446 in the first transmission/reception module 310, and an active optical cable (AOC) is directly attached to the cable (DAC). Module parameter information to be recognized as is stored.

Module parameter information includes nominal signaling rate, type of transmission rate selection function, link length, type of optical fiber supported, supplier name, IEEE company ID, serial number of product provided by supplier, supplier Manufacturing date code, part number provided by supplier, revision history of part number provided by supplier, laser wavelength, optical output power, optical input power, temperature, laser bias current ( Laser Bias Current) and module supply voltage (Module Supply Voltage).

In addition to storing serial IDs, vendor specifications, etc. in the internal storage of the second information management unit 486 in the second transmission/reception module 320, module parameter information for recognizing an active optical cable (AOC) as a direct attach cable (DAC) To save.

When the low power consumption active optical cable 200 is fastened to the data center (first host, second host), a procedure of recognizing the low power consumption active optical cable 200 is performed in fastening to the data center (first host, second host). Prior to this, the module parameter information is transmitted to the data center (first host, second host) first.

When the data center (first host, second host) receives module parameter information from the low power consumption active optical cable 200, it recognizes the active optical cable (AOC) as a direct attach cable (DAC) and then direct attach cable (DAC) ) To recognize the low power consumption active optical cable 200 by performing the same recognition procedure.

6 is a view showing the concept of an optical system included in the light transmission and reception assembly according to this embodiment.

The above-described features can be applied not only to an active optical cable, but also to a separate optical transmitter and receiver or various types of optical transmitter and receiver modules.

The first transmission/reception module 310 according to the present embodiment may be formed by including the first optical assembly 610.

The first optical assembly 610 is an assembly for transmitting and receiving light, and includes a first all-optical conversion element 524, a first collimator lens 620, a first reflector 630, and a first transmitter condensing lens unit for transmitting optical signals ( 640). Here, the first transmitter condenser lens unit 640 includes a first condenser lens 642 and a first spacer 644.

The first collimator lens 620 processes light emitted from the at least one first electro-optical conversion element 524 into a parallel first parallel beam. The first collimator lens 620 transmits the first parallel beam to the first reflector 630. Here, the set of rays is called a beam.

The first reflector 630 changes the traveling direction of the first parallel beam by a predetermined angle to form a second parallel beam. The first reflector 630 sends the second parallel beam, which has changed the path of the parallel beam from the first collimator lens 620 by 90°, to the first condenser lens 642.

The first condenser lens 642 condenses the second parallel beam and enters the first end located at a predetermined distance.

The thickness of the first spacer 644 in the x direction corresponds to a distance corresponding to a focal length of the first condenser lens 642. By forming the thickness of the first spacer 644 in the x direction to be equal to the focal length of the first condensing lens 642, light passing through the first condensing lens 642 may collect on the core of the optical fiber 650.

When the first optical assembly 610 according to the present embodiment is applied to the optical receiver, the roles of the collimator lens and the condensing lens in the functional side of the lens are reversed to those of the lenses applied to the optical transmitter. Hereinafter, a component including various individual functional elements will be referred to as an assembly.

The first optical assembly 610 is an assembly for transmitting and receiving light, and includes a first photoelectric conversion element 536, a fourth condenser lens 681, a fourth reflector 671, and a first receiver condenser lens unit for receiving an optical signal ( 661). Here, the first receiver condensing lens unit 661 includes a fourth collimator lens 663 and a fourth spacer 665.

The at least one first all-optical conversion element 524 and the at least one first photoelectric conversion element 536 are optically connected to the at least one optical link 430 using the first optical assembly 610. The first optical signal is light emitted while spreading from the at least one first all-optical conversion element 524.

The second transmission/reception module 420 according to the present embodiment may be implemented as the second optical assembly 620.

The second optical assembly 620 is an assembly for transmitting and receiving light, and includes a second all-optical conversion element 574, a third collimator lens 621, a third reflector 631, and a second transmitter condensing lens unit for transmitting optical signals ( 641). Here, the second transmitter condenser lens unit 641 includes a third condenser lens 632 and a third spacer 645.

The third collimator lens 621 processes light emitted from the second at least one second electro-optical conversion element 574 into a parallel third parallel beam. The third collimator lens 621 transmits the third parallel beam to the third reflector 631. Here, the set of rays is called a beam.

The third reflector 631 changes the traveling direction of the third parallel beam by a predetermined angle to form a fourth parallel beam. The third reflector 631 sends the fourth parallel beam, which has changed the path of the parallel beam from the third collimator lens 621 by 90°, to the third condensing lens 632.

The third condenser lens 632 condenses the fourth parallel beam and enters the second end located at a predetermined distance. The third optical signal is light emitted while spreading from the at least one second all-optical conversion element 574.

The thickness of the third spacer 645 in the x direction corresponds to a distance corresponding to a focal length of the first condenser lens 642. By forming the thickness of the third spacer 645 in the x-direction to be equal to the focal length of the third condenser lens 632, light passing through the third condenser lens 632 may collect on the core of the optical fiber 651.

When the second optical assembly 620 according to the present embodiment is applied to the optical receiver, the roles of the collimator lens and the condensing lens in the functional side of the lens are reversed to those of the lenses applied to the optical transmitter. Hereinafter, a component including various individual functional elements will be referred to as an assembly.

The second optical assembly 620 is an assembly for transmitting and receiving light, and includes a first photoelectric conversion element 536, a second condenser lens 680, a second reflector 670, and a second receiver condenser lens unit for receiving an optical signal 660). Here, the second receiver condenser lens unit 660 includes a second collimator lens 662 and a second spacer 664.

The at least one second all-optical conversion element 574 and the at least one second photoelectric conversion element 562 are optically connected to the at least one optical link 430 using the second optical assembly 620.

The above description is merely illustrative of the technical idea of the present embodiment, and those skilled in the art to which this embodiment belongs may be capable of various modifications and variations without departing from the essential characteristics of the present embodiment. Therefore, the present embodiments are not intended to limit the technical spirit of the present embodiment, but to explain, and the scope of the technical spirit of the present embodiment is not limited by these embodiments. The protection scope of the present embodiment should be interpreted by the claims below, and all technical spirits within the equivalent range should be interpreted as being included in the scope of the present embodiment.

200: Active optical cable (AOC)
202: first host unit 204: second host unit
310: first transmission/reception module 320: second transmission/reception module
330: optical link
420: first transmitter
402: first electric pad unit
442: first control unit 446: first information management unit
430: first receiver
460: second receiver
404: second electric pad unit
482: second control unit 486: second information management unit
470: second transmitter

Claims (17)

An optical link for transmitting optical signals input from outside of the first end and the second end in both directions, including a first end and a second end;
Convert the first electrical signal input from the outside into a first optical signal and transmit to the other side of the optical link using the first end or a second optical signal received from the opposite side of the optical link using the at least one optical link Is converted to a second electrical signal and output to the outside, the first optical signal is controlled by using the first information, which is at least one of pre-stored electrical and optical characteristics, temperature characteristics, and unique characteristic information, and the first A first transmission/reception module for generating, changing or deleting information;
A third optical signal input from the outside is converted into a third optical signal and transmitted to the first transmission/reception module using the second end or a fourth optical signal received from the first transmission/reception module using the second end Is converted to a fourth electrical signal and output to the outside, the third optical signal is controlled by using the second information, which is at least one of pre-stored electrical and optical characteristics, temperature characteristics, and unique characteristic information, and the second A second transmit/receive module that creates, changes or deletes information
Active optical cable comprising a. According to claim 1,
The first transmission and reception module,
A first electric pad unit for transmitting and receiving electrical signals to and from the external first host unit, driving at least one first electro-optical conversion element and the first electro-optical conversion element that convert the first electrical signal into the first optical signal. A first transmission unit having a first transmission circuit, at least one first photoelectric conversion element for converting the second optical signal to the second electrical signal and a first receiving circuit for driving the first photoelectric conversion element having a It includes a first receiver,
The second transmission and reception module,
A second electric pad unit for transmitting and receiving electrical signals to and from an external second host unit, driving at least one second electro-optical conversion element and the second electro-optical conversion element that convert the third electrical signal into the third optical signal. A second transmission unit having a second transmission circuit, at least one second photoelectric conversion element for converting the fourth optical signal to the fourth electrical signal and a second receiving circuit for driving the second photoelectric conversion element Active optical cable comprising a second receiver. According to claim 2,
The first transmission/reception module further includes a first control unit for controlling operations of the first transmission unit and the first reception unit, and a first non-volatile memory for storing the first information, and the The second transmission/reception module further includes a second control unit for controlling operations of the second transmission unit and the second reception unit, and a second nonvolatile memory for storing the second information. According to claim 3,
The first transmission/reception module performs an initialization operation with an external first host unit for a predetermined time before starting to transmit the first optical signal to the second transmission/reception module, and the second transmission/reception module performs the third An active optical cable, characterized in that performing an initialization operation with an external second host unit for a predetermined time before starting to transmit the optical signal to the first transmission/reception module. According to claim 4,
The first control unit controls the first transmission circuit so that the intensity of the optical signal generated by the at least one first all-optical conversion element is kept constant even when the temperature inside and outside the first transmission/reception module changes. 2 The control unit is an active type characterized in that it controls the second transmission circuit so that the intensity of the optical signal generated by the at least one second all-optical conversion element is maintained even when the temperature inside and outside the second transmission/reception module changes. Optical cable. According to claim 3,
The non-volatile memory,
Active optical cable characterized in that it is an electrically erasable and programmable read-only memory (EEPROM: Electrically Erasable Programmable Read-Only Memory). The method of claim 5,
The first transmission/reception module further includes a first information management unit for generating, changing, or deleting the first information, and the second transmission/reception module is a second information management unit for generating, changing, or deleting the second information. In addition,
The first information management unit generates the third information by updating the first information by creating, changing or deleting at least one of the type of the first transmission/reception module and the type of the first electric pad unit, and the second information management unit An active optical cable characterized in that the second information is updated by generating, changing, or deleting at least one of the type of the second transmission/reception module and the type of the second electric pad unit. The method of claim 7,
The first control unit causes the first information management unit to generate fifth information updating the third information based on module parameter information previously stored in the first nonvolatile memory according to the result of the initialization operation,
The second control unit may generate the sixth information that updates the fourth information based on the module parameter information previously stored in the second nonvolatile memory according to the result of the initialization operation. Active optical cable. The method of claim 8,
The module parameter information,
Nominal signaling rate, type of transmission rate selection function, link length, type of optical fiber supported, supplier name, IEEE company ID, serial number of product provided by supplier, manufacturer's manufacturing date code, Part number provided by supplier, revision history of part number provided by supplier, laser wavelength, optical output power, optical input power, temperature, laser bias current And a module supply voltage. According to claim 1,
At least one of the first optical signal, the second optical signal, the third optical signal, and the fourth optical signal is pulse-amplitude modulation using at least two bits of logical information values per unit clock pulse. Active optical cable, characterized in that the optical signal generated based on the Amplitude Modulation) technique. The method of claim 10,
The method of claim 7,
The pulse amplitude modulation technique is an active optical cable, characterized in that it comprises PAM-4, PAM-8 and PAM-16. The method of claim 11,
The first transmission and reception module and the second transmission and reception module,
Active optical cable comprising at least one retimer (Retimer) and at least one equalizer (Equalizer). According to claim 1,
The optical link,
An active optical cable comprising at least one optical fiber, wherein one end of the at least one optical fiber is connected to the first transmitter, and the other end of the at least one optical fiber is connected to the second receiver. The method of claim 13,
The at least one first photoelectric conversion element and the at least one first photoelectric conversion element are optically connected to the optical link using a first optical assembly, and the at least one second electro-optical conversion element and the at least one The second photoelectric conversion element is an active optical cable characterized in that it is optically connected to the optical link using a second optical assembly. The method of claim 14,
The first optical assembly,
A first lens that processes light emitted from the first electro-optical conversion element while spreading into a first parallel beam in a parallel shape, and changes a traveling direction of the first parallel beam by a predetermined angle to form a second parallel beam. It is formed integrally with a first mirror and a second lens that converges the second parallel beam and enters the first end located at a predetermined distance.
The second optical assembly,
A third lens that processes light emitted from the second electro-optical conversion element and spreads into a third parallel beam of a parallel shape, and changes a traveling direction of the third parallel beam by a predetermined angle to form a fourth parallel beam. An active optical cable comprising a second mirror and a fourth lens that converges the fourth parallel beam and enters the second end positioned at a predetermined distance. The method of claim 9,
The first control unit is formed integrally with the first information management unit, the second control unit is an active optical cable characterized in that it is formed integrally with the second information management unit. The method of claim 16,
The first information management unit is formed integrally with the first non-volatile memory, and the second information management unit is formed integrally with the second non-volatile memory.

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