KR102228114B1 - Active Optical Cable - Google Patents

Abstract

Disclosed is an active optical cable.
In this embodiment, since there is no need to have a separate monitoring photodetector applied to a general optical transceiver, it is possible to improve the optical coupling efficiency by increasing the current-optical output linearity without a complicated structure, and to improve the transmission/reception electro-optical characteristics at both ends of the module. By converting into a library, power consumption can be reduced by allowing the optical output from the light source included in the optical transmitter to maintain high linearity over a wide temperature range, and an active optical cable that can apply a multilevel PAM technique having a level of 4 or higher is provided. do.

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 the prior art.

In recent years, in order to provide a service using a new relay platform such as a social networking service (SNS) and one-person media in a high-performance mobile device, a wider bandwidth is required than before.

For example, the Cisco Visual Networking Index 2018 predicts that the number of network-connected devices per person will exceed 3.6 due to the development of IoT (Internet of Things) and 5G mobile communication network technology. In addition, the Internet data usage per person per month in 2022 is predicted to be 85 GB. It is predicted that the share of video in the total data traffic of Internet data usage will exceed 80% in 2022 from 70% in 2017.

If the explosively increasing data traffic is classified by destination, it can be divided into inside a data center, between a data center and a data center, and between a data center and users. More than 70% of global data traffic occurs inside data centers. The vast majority of data generated around the world is due to the production, processing, storage, and authentication of data generated inside the data center.

The Optical Interconnect Solution can solve the recent explosive increase in data traffic within the data center. Optical connectivity solutions have already replaced copper-based connectivity in long-distance and metropolitan communications networks. The applicable area of the optical connection solution is gradually expanding with the increase of bandwidth and the development of optical communication technology. One of the representative forms of providing such an optical connection solution to a mid- to long-distance optical connection solution is the Optical Transceiver.

From the user's point of view, a typical optical transceiver has an electrical interface and an optical interface at the same time. When connecting two devices using a general optical transceiver, a patch cord is required to connect two optical transceivers and two optical transceivers. Two general optical transceivers must be designed and manufactured to suit the electro-optical characteristics of optical signals transmitted and received by each optical transceiver. In order to use the optical transceiver normally, the user selects one of the two optical transceivers required. Thereafter, the user must select another optical transceiver suitable for the selected optical receiver and install it on the other side.

The optical signal transmitted from one optical transceiver to the other optical transceiver needs to be monitored in real time, and the size of the optical signal emitted from the transmitter must be increased or decreased according to the conditions of the optical link.

When adjusting the size of the optical signal according to the condition of the optical link, a Monitoring Photodetector (MPD) is placed near the light source of the transmitter. The monitoring photodetector monitors the light output from the light source in real time. Similar to the above-described optical transceiver structure, a monitoring photodetector is also used in the case of an optical transceiver using a multi-level pulse amplitude modulation (PAM-N, N is a natural number greater than 2) technique. Should be.

For example, in the case of using the PAM-4 technique that divides the signal size into four levels, the size of the optical signal emitted from the transmitter is determined in real time in order to secure a sufficient Extinction Ratio (ER) of the optical signal emitted from the optical transmitter. It needs to be monitored and controlled. Even in this case, a monitoring photodetector is usually used.

In order to monitor and control the optical signal emitted from the optical transceiver in real time, a general optical transceiver requires a monitoring photodetector located close to the light source inside the optical transceiver, and some of the optical signals emitted from the light source are input to the monitoring photodetector. It must have an optical system that can be used.

Moreover, when the light source is a vertical emitting type laser rather than a side emitting type (Edge-Emitting Type or In-Plane Type) laser, optical coupling between the light source and the monitoring photodetector is more difficult. In other words, manufacturing and mass production of individual optical transceivers with vertical emission type lasers is more difficult compared to manufacturing and mass production of individual optical transceivers with side emission type lasers.

SFP (Small Form Factor Pluggable) type active optical cable shown in Fig.1(a) that is structurally similar to the optical transceiver or QSFP(Quad Small Form Factor Pluggable) type active type shown in Fig.1(b) Optical cables have only an electrical interface. In the optical transmission/reception module at both ends of the SFP active optical cable or QSFP active optical cable, testing and setting of optical devices and electronic devices can be completed during the manufacturing process, so it is not always necessary to monitor the optical output of the light source as in a typical optical transceiver. That is, in the case of an active optical cable having such a structure, the performance and functions are the same as those of the optical transceiver, while installation, maintenance and management are relatively easy.

Therefore, while being able to utilize the advantages of such an active optical cable, it does not use a monitoring photodetector, and without a complex structure and high-cost device, it is possible to improve the optical coupling efficiency by increasing the current-optical output linearity. A device for optical transmission and reception is required.

In this embodiment, since there is no need to have a separate monitoring photodetector applied to a general optical transceiver, it is possible to improve optical coupling efficiency by increasing current-optical output linearity without a complicated structure, and to improve the transmission/reception electro-optical characteristics of both ends of the module. By converting into a library, power consumption can be reduced by allowing the optical output from the light source included in the optical transmitter to maintain high linearity over a wide temperature range, and an active optical cable that can apply a multilevel PAM technique having a level of 4 or more is provided. There is a purpose to do it.

According to an aspect of the present embodiment, there is provided an optical link including a first end and a second end to transmit an optical signal between the first end and the second end in both directions; Converts the first electrical signal input from the first host unit into a first optical signal and then transmits it from the first end to the second end or converts a second optical signal received from the second end into a second electrical signal A first transmission/reception module configured to output the output to the first host unit and to control the magnitude of the first optical signal according to a previously stored electro-optical characteristic and temperature; Converts a third electrical signal input from the second host into a third optical signal, and then transmits it from the second end to the first end or converts a fourth optical signal received from the second end into a fourth electrical signal. Thus, while outputting to the second host unit, it provides an active optical cable, characterized in that it comprises a second transmission and reception module for controlling the size of the third optical signal according to the previously stored electro-optical characteristics and temperature.

As described above, according to the present embodiment, since there is no need to provide a separate monitoring photodetector applied to a general optical transmitter and receiver, it is possible to improve optical coupling efficiency by increasing current-light output linearity without a complicated structure. By converting the electro-optical characteristics of both ends into a library, the light output from the light source included in the optical transmitter can maintain high linearity over a wide temperature range, thereby reducing power consumption.

According to this embodiment, without a monitoring photodetector (MPD) in the transmission unit, the transmission unit is output by controlling the transmission unit by using the relationship between the electro-optical characteristics and temperature between the transmission unit and the reception unit stored in a reference table (Lookup Table). There is an effect of keeping the size of the optical signal uniform.

According to another aspect of the present embodiment, by providing an accurate driving current to the light source, there is an effect of providing various types of optical transmission and reception devices requiring a light source having a high linearity light output-current (LI) characteristic. have.

1 is a view showing a general active optical cable.
2 is a diagram showing an example of application of an active optical cable according to the present embodiment.
3 is a diagram for explaining a method of monitoring an optical signal using a monitoring photodetector (MPD) in an optical transceiver.
4 is a view for explaining an active optical cable having an electric signal reference table according to the present embodiment.
5 is a schematic diagram illustrating a function of an active optical cable according to the present embodiment.
6 is a diagram illustrating a method of storing information in a reference table by connecting an active optical cable according to the present embodiment to a test apparatus.
7 is a diagram showing an electric signal reference table according to the present embodiment.
8 is a diagram showing the concept of an optical system included in the optical transmission/reception module according to the present embodiment.

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

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

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

2A, the active optical cable 200 according to the present embodiment connects the first host unit 202 and the second host unit 204 to provide data from the first host unit 202. Is transferred to the second host unit 204, and data from the second host unit 204 is transferred to the first host unit 202. The first host unit 202 and the second host unit 204 may be one selected from among network devices that perform functions as a server, a switch, and a storage.

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

3 is a diagram for explaining a method of monitoring an optical signal using a monitoring photodetector (MPD) in an optical transceiver.

In FIG. 3A, for convenience of explanation, only transmission/reception channels in one direction are shown. That is, illustrations of the receiver included in the same module as the transmitter Tx shown on the left and the transmitter included in the same module as the receiver Rx shown on the right are omitted.

As shown in (a) of FIG. 3, in the case of a general optical transceiver, the transmission unit Tx and the reception unit Rx are included in each of two separate optical transceivers or optical transmission/reception modules, and are connected by an optical link. The three components that form one optical path, the transmitter (Tx), receiver (Rx), and optical link, are sold as separate finished products before they are actually operated. Optical transceivers and optical links should be selected for smooth operation.

Due to the intrinsic characteristics of the separated optical transceiver, the characteristics of the optical signal transmitted by the transmitting unit Tx may change before reaching the receiving unit Rx. For example, the temperature of the surrounding environment in which the transmitter (Tx) is installed and the temperature of the surrounding environment in which the receiver (Rx) is installed may be different, and the size of the optical signal transmitted by the transmitter (Tx) is that of the optical signal requested by the receiver (Rx). It can be larger or smaller than the size. In this case, a larger current may be applied to the all-optical conversion element of the transmission unit Tx so that the transmission unit Tx can output a larger optical signal.

In the case of a conventional optical transceiver, a monitoring photodetector MPD is disposed in the transmission unit Tx in order to accurately adjust the size of the optical signal output from the transmission unit Tx. The transmission unit (Tx) of a conventional optical transmitter and receiver includes an optical unit (Optics) including at least one light source and at least one monitoring photodetector (MPD).

Optics refers to a part that generates, modulates, and detects an optical signal. The light source and the monitoring photodetector MPD may be an all-optical conversion device and a photoelectric conversion device, respectively. Typically, the electro-optical conversion device is driven by two parameters: a bias current and a modulation current. The monitoring photodetector (MPD) included in the transmitter (Tx) receives a part of the optical signal output from the light source and determines the size of the optical signal transmitted by the light source through the part. Carry out.

Typically, in order to receive a part of an optical signal output from a light source, an additional separate optical system, such as an optical splitter and an optical isolator, should be additionally provided.

When a side-emitting laser is used as a light source, some of the optical signals emitted from the light source are emitted to one side, and the other part of the optical signal is emitted to the other. The monitoring photodetector (MPD) is placed on the other side rather than the one to be used as an output, and receives the optical signal emitted in the direction in which the monitoring photodetector (MPD) is located, and monitors the light emitted in the direction used as an output. You can determine the size of the signal.

In the case of the optical transmitter/receiver shown in FIG. 3A, the size of the optical output output from the transmitter Tx may be controlled by the method shown in FIG. 3B. Conventional optical signal control in an optical transceiver is a correlation between the size of the optical signal output from the transmitter (Tx) and the size of the electrical signal that the receiver (Rx) receives the optical signal photoelectrically converts and outputs the optical signal. , For example, calculate (Normalization) a correlation between the magnitude of the optical signal of the transmitter (Tx) and the magnitude of the current of the receiver (Rx), and adjust the magnitude of the optical output output from the transmitter (Tx) based on this or a desired value Control (Feedback) to maintain In this case, in order to adjust the size of the optical signal output from the transmission unit Tx, the size of the optical signal measured in real time by the monitoring photodetector MPD is used. This optical signal control is called Automatic Power Control (APC). Here, the optical signal output from the transmission unit Tx is detected by the receiving unit Rx and converted into a current value may be used as a received signal strength indicator (RSSI), which is an index. Here, the role of receiving the optical signal output from the transmission unit Rx and converting it into a current is performed by the photodetector PD.

4 is a view for explaining an active optical cable having an electric signal reference table according to the present embodiment.

In FIG. 4A, for convenience of explanation, only transmission/reception channels in one direction are shown. That is, illustrations of the receiver included in the same module as the transmitter shown on the left and the transmitter included in the same module as the receiver shown on the right are omitted.

As shown in (a) of FIG. 4, the active optical cable 200 according to an embodiment of the present invention includes a first transmission/reception module 410, a second transmission/reception module 420, and an optical link 430. . Each of the first transmission/reception module 410 and the second transmission/reception module 420 includes both a transmission unit and a reception unit, but for convenience of explanation, only the transmission unit is illustrated in the case of the first transmission/reception module 410, and the second transmission/reception module In the case of 420, only the receiver is shown.

In the case of the active optical cable 200 shown in FIG. 4A, the size of the optical signal output from the transmission unit, that is, a light source may be controlled by the method shown in FIG. 4B.

In the optical signal control of the active optical cable 200 according to an embodiment of the present invention, the size of the optical signal output from the transmitting unit Tx and the receiving unit Rx receiving the optical signal photoelectrically convert the optical signal and output the optical signal. Correlation between the magnitudes of the electric signals, for example, the current output from the receiver Rx is calculated (Normalized) according to the magnitude of the optical signal output from the transmitter Tx, and based on this, the current output from the transmitter Tx The size of the optical signal is adjusted or the size of the optical signal output from the transmitter Tx is controlled to maintain a desired value.

Here, in order to adjust the size of the optical signal output from the transmission unit (Tx), the active optical cable 200 according to an embodiment of the present invention includes the electro-optical characteristics between the transmission unit (Tx) and the reception unit (Rx) stored in advance, and Use the temperature characteristics. In this case, the transmission unit Tx uses only the size of the electric signal generated by photoelectric conversion in the reception unit Rx in order to control the size of the optical signal output from the transmission unit Tx. When controlling the size of the signal, the correlation between the electro-optical characteristics and the temperature characteristics between the transmission unit (Tx) and the reception unit (Rx) stored in advance is used. Here, the correlation between the electro-optical characteristics and the temperature characteristics between the transmission unit Tx and the reception unit Rx is stored in the first transmission/reception module 410 side including the transmission unit Tx in the form of a lookup table.

The optical signal output from the transmission unit Tx is detected by the receiving unit Rx and converted into a current, and a value converted into a current may be used as an RSSI value, which is an index. Here, the role of receiving the optical signal output from the transmission unit Rx and converting it into a current is performed by the photodetector PD.

Here, the optical signal control shown in (a) and (b) of FIG. 4 is not only an active optical cable, but also an optical link-coupled optical formed by combining an optical link with a conventional optical transceiver or one optical transceiver. It can also be applied to transmission and reception devices.

5 is a schematic diagram illustrating a function of an active optical cable according to the present embodiment.

The active optical cable 200 according to an embodiment of the present invention includes a first transmission/reception module 410, a second transmission/reception module 420 and an optical link 430. The active optical cable 200 shown in FIG. 5 is an example of an active optical cable including an optical link including one channel, and can be applied to an active optical cable including at least one channel. For example, in the case of an active optical cable having an SFP, QSFP or OSFP structure, it is implemented as an optical link including 1, 4, or 8 transmission/reception channels, respectively. Here, assuming that each of the transmission/reception channels can transmit optical signals in one direction, an active optical cable having an SFP, QSFP, or OSFP structure may be formed to have 2, 8, or 16 channels, respectively. Here, each channel is formed in the form of an optical waveguide including an optical fiber.

An optical signal is transmitted between the first transmission/reception module 410 and the second transmission/reception module 420 via the optical link 430 as a medium, and an electrical-optical conversion device and an optical-electrical conversion device. Conversion Device) and the optical link between the optical link 430 is made using an integrated optical assembly including a lens and a reflector.

The first transmission/reception module 410 includes a first transmission unit 520, a first reception unit 530, a first control unit 542, a first reference table 544, and a first electric pad unit 502.

The first transmission/reception module 410 converts a first electric signal input from an external first host unit 202 into a first optical signal, and It transmits to a second end connected to the transmission/reception module 420. Here, the first end means one end of the optical link 430 that is physically and optically connected seamlessly to the first transmission/reception module 410 of the optical links 430. The second end means the other end of the optical link 430 that is physically and optically connected seamlessly to the second transmission/reception module 420 of the optical link 430. Here, the first host unit 202 is one of network devices that perform functions as a server, a switch, and a storage, as described with reference to FIG. 2.

The first transmission unit 520 may include at least one first electro-optical conversion element 524 and a first transmission circuit 526 driving the same. The first electro-optical conversion element 524 is an element that converts an electrical signal into an optical signal, and is a semiconductor laser such as a Distributed Feedback (DFB) laser, a Vertical-cavity Surface-Emitting Laser (VCSEL), and a Distributed Bragg Reflector (DBR) laser. It is desirable. The first transmission circuit 526 serves to drive the first electro-optical conversion element 524 by receiving an electric signal. The first transmission circuit 526 may increase or decrease the size of an electric signal applied to the first electro-optical conversion element 524 based on an electric signal received from the outside, and the first electro-optical conversion element 524 It is also possible to readjust the timing of the electrical signal applied to the. That is, the first transmission circuit 526 adjusts the magnitude or timing of the current input to the first electro-optical conversion element 524 according to a preset condition or control, Characteristics can be changed. In this case, the function of adjusting the magnitude or timing of the current may be implemented separately as a separate component.

Here, the first transmission circuit 526 is based on the electric signal input from the first host unit 202 through the first electric pad unit 502 and the electric signal input from the first control unit 542 The conversion element 524 can be driven.

In addition, the first transmission unit 520 converts the first electrical signal into a first optical signal and transmits it to the second transmission/reception module 420 through the first end of the optical link 430. The first transmission unit 520 uses the information stored in the first reference table 544 to find a first linear section in which the change in the first output current value changes linearly with respect to the change in the first input current value. The input current value may be set to be located at an average value or an intermediate value of the first linear section.

In addition, the first transmission unit 520 divides the section in which the change in the first output current value appears in relation to the change in the first input current value into a plurality of sections by using the information stored in the first reference table 544. The first input current value may be set to operate within the period.

In addition, the first transmission unit 520 may further include a first temperature sensor that senses a first temperature, which is a temperature in the first transmission unit 520.

Each component included in the first transmission unit 520 is connected to a communication path connecting a software module or a hardware module inside the device, so that they can operate organically with each other. These components communicate using one or more communication buses or signal lines.

Each component of the first transmission unit 520 shown in FIG. 5 refers to a unit that processes at least one function or operation, and may be implemented as a software module, a hardware module, or a combination of software and hardware.

The first receiving unit 530 may include a first photoelectric conversion element 536 and a first receiving circuit 534. The first photoelectric conversion element 536 converts a second optical signal, which is an optical signal received from the second transmission/reception module 420, into a second electric signal. The first receiving circuit 534 receives the second electric signal generated by the conversion of the first photoelectric conversion element 536 and outputs the received second electric signal to the first host unit 202 through the first electric pad unit 502. The first receiving circuit 534 may increase or decrease the size of the electric signal output to the first host unit 202 according to a preset condition or control, and may readjust the timing of the output electric signal.

Here, the first receiving circuit 534 is based on the electric signal input from the first photoelectric conversion element 536 and the electric signal input from the first control unit 542, the electricity output to the first electric pad unit 502 You can control the signal.

In addition, the first transmission circuit 526 and the first reception circuit 534 are pulse amplitude modulation including PAM4, PAM8, and PAM16 using at least two bits of logical information value per unit clock pulse. An electric signal generated by driving the first electro-optical conversion element 524 or photoelectrically converting from the first photoelectric conversion element 536 may be processed based on a modulation) technique.

The first control unit 542 is electrically connected to the first transmission circuit 526, the first reception circuit 534, and the first electric pad unit 502, and the first transmission circuit 526 or the first reception circuit ( 534). The first control unit 542 includes a first transmission circuit 526 or a first reception circuit based on a predetermined condition or an electric signal from the first host unit 202 input through the first electric pad unit 502. You can control (534). Also, the first control unit 542 may control the first transmission circuit 526 or the first reception circuit 534 based on information previously stored in the first reference table 544.

Control of the optical signal output from the first transmission unit 520 included in the first transmission/reception module 410 and received by the second reception unit 560 included in the second transmission/reception module 420 is performed by the first transmission unit 520 It is performed by using a correlation between the magnitude of the output optical signal and the magnitude of the electric signal that the second receiver 560 receives the optical signal photoelectrically converts and outputs the optical signal. That is, according to the magnitude of the optical signal output from the first transmitter 520, the magnitude of the current output from the second receiver 560 is calculated (Normalized), and based on this, the light output from the first transmitter 520 The size of the signal is adjusted or the size of the optical signal output from the first transmission unit 520 is controlled to maintain a desired value.

Here, in order to adjust the size of the optical output output from the first transmission unit 520, the active optical cable 200 according to an embodiment of the present invention includes a first transmission unit 520 and a second reception unit 560 stored in advance. Between the electro-optical properties and the temperature properties are utilized. In this case, the first transmission unit 520 uses only the size of the electric signal generated by photoelectric conversion by the second reception unit 560 in order to control the size of the optical signal output from the first transmission unit 520. When controlling the size of the optical signal output from the transmission unit 520, the correlation between the electro-optical characteristics and the temperature characteristics stored in advance between the first transmission unit 520 and the second reception unit 560 is used. Here, the correlation between the electro-optical characteristics and the temperature characteristics between the first transmission unit 520 and the second reception unit 560 is stored in the first transmission/reception module 410 side including the first transmission unit 520 in the form of a lookup table. do. Here, the lookup table may include a first reference table 544, and the first reference table 544 may be stored in a non-volatile memory included in the first transmission/reception module 410. .

The first control unit 542 may control the magnitude of the first optical signal by using an electro-optical characteristic of the second receiver 560 and a current value corresponding to a temperature among information stored in the first reference table 544.

In addition, when the current temperature is within the reference temperature range, the first control unit 542 causes the first transmission circuit 526 to apply a current corresponding to the first input current compensation value to the first electro-optical conversion element 524. , The magnitude of the first optical signal output from the first electro-optical conversion element 524 may be adjusted to compensate for a deviation by a first reference optical output value corresponding to the first input current value.

In addition, when the current temperature is out of the reference temperature range, the first control unit 542 causes the first transmission circuit 526 to apply a current corresponding to the first compensation current value for each temperature to the first electro-optical conversion element 524. Thus, the magnitude of the first optical signal output from the first electro-optical conversion element 524 is adjusted to compensate for temperature variation by a first reference optical output value corresponding to the first input current value.

The first reference table 544 stores an electro-optical characteristic of the second receiver 560 and a compensation current value according to temperature. The first reference table 544 stores a first input current value, which is a bias current value input to at least one first electro-optical conversion element 524. The first reference table 544 stores a first output current value output from the second receiver 560 in response to a first input current value.

The first reference table 544 stores a first input current compensation value for compensating the first output current value when the first output current value is different from the preset first reference value. The first reference table 544 may additionally store a first input current value, a first output current value, and a first input current compensation value according to a change in the first temperature sensed by the first transmitter 520.

Here, the first input current value may be a value in which both the bias current value and the modulation current value are considered.

The second transmission/reception module 420 includes a second transmission unit 570, a second reception unit 560, a second control unit 582, a second reference table 584, and a second electric pad unit 504.

The second transmission/reception module 420 converts the third electrical signal input from the external second host unit 204 into a third optical signal, and It transmits to a first end connected to the transmission/reception module 410. Here, the second end means one end of the optical link 430 that is physically and optically seamlessly connected to the second transmission/reception module 420 among the optical links 430. Here, the second host unit 204 is one of network devices that perform functions as a server, a switch, and a storage, as described in FIG. 2.

The second transmission unit 570 may include at least one second electro-optical conversion element 574 and a second transmission circuit 572 driving the same. The second electro-optical conversion element 574 is an element that converts an electric signal into an optical signal, and is a semiconductor laser such as a distributed feedback (DFB) laser, a vertical-cavity surface-emitting laser (VCSEL), and a distributed bragg reflector (DBR) laser. It is desirable. The second transmission circuit 572 serves to drive the second electro-optical conversion element 574 by receiving an electric signal. The second transmission circuit 572 may increase or decrease the size of the electric signal applied to the second electro-optical conversion element 574, based on the electric signal received from the outside, and the second electro-optical conversion element 574 It is also possible to readjust the timing of the electrical signal applied to the. That is, the second transmission circuit 572 adjusts the magnitude or timing of the current input to the second electro-optical conversion element 574 according to a preset condition or control, Characteristics can be changed. In this case, the function of adjusting the magnitude or timing of the current may be implemented separately as a separate component.

Here, the second transmission circuit 572 is based on the electric signal input from the second host unit 204 through the second electric pad unit 504 and the electric signal input from the second control unit 582 The conversion element 574 can be driven.

In addition, the second transmission unit 570 converts the third electrical signal into a third optical signal and transmits it to the first transmission/reception module 410 through the second end of the optical link 430. The second transmitter 570 uses the information stored in the second reference table 584 to find a second linear section in which the change in the second output current value changes linearly with respect to the change in the second input current value. The input current value may be set to be located at an average value or an intermediate value of the second linear section.

In addition, the second transmission unit 570 divides the section in which the change in the first output current value appears in relation to the change in the first input current value into a plurality of sections by using the information stored in the second reference table 584. The second input current value may be set to operate within the period.

In addition, the second transmitter 570 may further include a second temperature sensor that senses a second temperature, which is a temperature in the second transmitter 570.

Each component included in the second transmission unit 570 is connected to a communication path connecting a software module or a hardware module inside the device, so that they can operate organically with each other. These components communicate using one or more communication buses or signal lines.

Each component of the second transmitter 570 shown in FIG. 5 refers to a unit that processes at least one function or operation, and may be implemented as a software module, a hardware module, or a combination of software and hardware.

The second receiving unit 560 may include a second photoelectric conversion element 562 and a second receiving circuit 564. The second photoelectric conversion element 562 converts a fourth optical signal, which is an optical signal received from the first transmission/reception module 410, into a fourth electric signal. The second receiving circuit 564 receives the fourth electric signal generated by photoelectric conversion by the second photoelectric conversion element 562 and outputs it to the second host unit 204 through the second electric pad unit 504. The second receiving circuit 564 may increase or decrease the size of the electric signal output to the second host unit 204 according to a preset condition or control, and may readjust the timing of the output electric signal.

Here, the second receiving circuit 564 is based on the electric signal input from the second photoelectric conversion element 562 and the electric signal input from the second control unit 582, the electricity output to the second electric pad unit 504 You can control the signal.

In addition, the second transmission circuit 572 and the second reception circuit 564 are pulse amplitude modulation including PAM4, PAM8 and PAM16 using at least two bits of logical information value per unit clock pulse. An electric signal generated by driving the second electro-optical conversion element 574 or photoelectrically converting from the second photoelectric conversion element 562 may be processed based on a modulation method.

The second control unit 582 is electrically connected to the second transmission circuit 572, the second reception circuit 564, and the second electric pad unit 504, and the second transmission circuit 572 or the second reception circuit ( 564). The second control unit 582 is a second transmission circuit 572 or a second reception circuit based on a preset condition or an electric signal from the second host unit 204 input via the second electric pad unit 504. (564) can be controlled. Also, the second control unit 582 may control the second transmission circuit 572 or the second reception circuit 564 based on information previously stored in the second reference table 584.

Control of the optical signal output from the second transmission unit 570 included in the second transmission/reception module 420 and received by the first reception unit 530 included in the first transmission/reception module 410 is performed by the second transmission unit 570. It is performed by using a correlation between the magnitude of the output optical signal and the magnitude of the electric signal that the first receiving unit 530 that receives the optical signal photoelectrically converts and outputs the optical signal. That is, the current output from the first receiver 530 is calculated (Normalized) according to the size of the optical signal output from the second transmitter 570, and based on this, the optical signal output from the second transmitter 570 is The size is adjusted or the size of the optical signal output from the second transmission unit 570 is controlled to maintain a desired value.

Here, in order to adjust the size of the optical output output from the second transmission unit 570, the active optical cable 200 according to an embodiment of the present invention includes a second transmission unit 570 and a first reception unit 530 stored in advance. Between the electro-optical properties and the temperature properties are utilized. In this case, the second transmission unit 570 uses only the size of the electric signal generated by photoelectric conversion by the first reception unit 530 in order to control the size of the optical signal output from the second transmission unit 570, and the second When controlling the size of the optical signal output from the transmission unit 570, a correlation between the electro-optical characteristics and temperature characteristics stored in advance between the second transmission unit 570 and the first reception unit 530 is used. Here, the correlation between the electro-optical characteristics and the temperature characteristics between the second transmission unit 570 and the first reception unit 530 is stored in the second transmission/reception module 420 side including the second transmission unit 570 in the form of a lookup table. do. Here, the lookup table may include a second reference table 584, and the second reference table 584 may be stored in a nonvolatile memory included in the second transmission/reception module 420.

The second control unit 582 may control the magnitude of the third optical signal by using an electro-optical characteristic of the first receiving unit 530 and a current value corresponding to a temperature among information stored in the second reference table 584.

In addition, the second control unit 582 causes the second transmission circuit 572 to apply a current corresponding to the second input current compensation value to the second electro-optical conversion element 574 when the current temperature is within the reference temperature range. , The magnitude of the third optical signal output from the second electro-optical conversion element 574 may be adjusted to compensate for a deviation by a second reference optical output value corresponding to the second input current value.

In addition, when the current temperature is out of the reference temperature range, the second control unit 582 causes the second transmission circuit 572 to apply a current corresponding to the compensation current value for each second temperature to the second electro-optical conversion element 574. Thus, the magnitude of the third optical signal output from the second electro-optical conversion element 574 is adjusted to compensate for temperature variation by a second reference optical output value corresponding to the second input current value.

The second reference table 584 stores electro-optical characteristics of the first receiver 530 and a compensation current value according to temperature. The second reference table 584 stores a second input current value, which is a bias current value input to at least one second electro-optical conversion element 574. The second reference table 584 stores a second output current value output from the first receiver 530 in response to a second input current value.

The second reference table 584 stores a second input current compensation value for compensating the second output current value when the second output current value is different from the preset second reference value. The second reference table 584 may additionally store a second input current value, a second output current value, and a second input current compensation value according to a change in the second temperature sensed by the second transmitter 570.

Here, the second input current value may be a value in which both the bias current value and the modulation current value are considered.

The optical link 430 may include at least one optical fiber. One end of the optical fiber included in the optical link 430 is connected to the output terminal of the first transmission unit 520. The other end of the at least one optical fiber is connected to the input end of the second receiver 560. One end of at least one other optical fiber is connected to the output terminal of the second transmission unit 570. The other end of the at least one other optical fiber is connected to the input end of the first receiver 530.

At least one of the first optical signal, the second optical signal, the third optical signal, and the fourth optical signal is a pulse amplitude modulation technique using at least two bits of logical information value per unit clock pulse. It is an optical signal generated on the basis of. Pulse amplitude modulation techniques include PAM-4, PAM-8 and PAM-16.

At least one of the first transmission/reception module 410 and the second transmission/reception module 420 may include at least one of a retimer and an equalizer.

6 is a diagram illustrating a method of storing information in a reference table by connecting an active optical cable according to the present embodiment to a test apparatus.

As shown in FIG. 6, the low power consumption active optical cable 200 operating in a wide temperature range is connected to the test apparatus 600 using the first electric pad part 502 and the second electric pad part 504. . The low power consumption active optical cable 200 stores values set by the test device 600 in the provided first reference table 544 and second reference table 584.

The test apparatus 600 is connected to the first electric pad unit 502 and the second electric pad unit 504 and sets values stored in the first reference table 544 and the second reference table 584. You can have the product shipped.

7 is a diagram showing an electric signal reference table according to the present embodiment.

The first reference table 544 stores a first input current value (eg, 3 mA) applied to the first transmission unit 520. The first reference table 544 stores a first output current value (eg, 100 μA, 70 μA, 50 μA, 60 μA) output from the second receiver 560 in response to the first input current value. The first reference table 544 is a first input current compensation value (e.g., 3 mA, 4 mA, 5 mA, 4.5 mA) for compensating for a deviation according to optical characteristics by a first reference optical output value corresponding to the first input current value. ). The first reference table 544 is a first compensation current value for each temperature (e.g., 25°C compensation current value (3 mA, 4 mA)) that compensates for temperature deviation by a first reference light output value corresponding to the first input current value. , 5 mA, 4.5 mA), 50°C compensation current value (3.9 mA, 5.2 mA, 6.5 mA, 4.85 mA), 60°C compensation current value (4.2 mA, 5.6 mA, 7 mA, 5.3 mA), 70° C Save the compensation current values (4.5 mA, 6 mA, 7.5 mA, 6.75 mA)).

The second reference table 584 stores a second reference current value (eg, 3 mA) applied to the second transmitter 570. The second reference table 584 stores second output current values (eg, 100 μA, 70 μA, 50 μA, and 60 μA) output from the first receiver 530 in response to the second reference current value. The second reference table 584 is a second input current compensation value (e.g., 3 mA, 4 mA, 5 mA, 4.5 mA) for compensating for a deviation according to optical characteristics by a first reference optical output value corresponding to the second reference current value. ). The second reference table 584 is a second temperature-specific compensation current value (e.g., 25°C compensation current value (3 mA, 4 mA, 5)) that compensates for temperature deviation by a first reference light output value corresponding to the reference current value. mA, 4.5 mA), 50°C compensation current value (3.9 mA, 5.2 mA, 6.5 mA, 4.85 mA), 60°C compensation current value (4.2 mA, 5.6 mA, 7 mA, 5.3 mA), 70°C compensation Save the current values (4.5 mA, 6 mA, 7.5 mA, 6.75 mA)).

The active optical cable 200 according to the present embodiment ultimately checks in real time how the size of the optical signal output by the light source included in the transmission unit (the first transmission unit 520, the second transmission unit 570) changes in real time, and a lookup table (1st reference table 544, 2nd reference table 584) form, and this lookup table (1st reference table 544, 2nd reference table 584) is transmitted to the transmission part (the 1st transmission part 520 ), included in the second transmission unit 570).

A simple microcontroller unit (MCU) (first control unit 542, second control unit 582) is included in the transmission unit (first transmission unit 520, second transmission unit 570) in the active optical cable 200.

A lookup table (a first reference table 544, a second reference table 584) is included in a memory included inside or outside the MCU (the first control unit 542 and the second control unit 582). The transmission unit (the first control unit 542, the second control unit 582) controls the current value based on the information stored in the lookup table (first reference table 544, second reference table 584). The light sources in the first transmission unit 520 and the second transmission unit 570 are driven.

A temperature sensor is included in the transmitting/receiving module to compensate for changes in temperature. For example, the size of the optical signal output from the light source included in the transmission unit (the first transmission unit 520 and the second transmission unit 570) is 100% at 25°C. When the temperature of the transmission unit (the first transmission unit 520 and the second transmission unit 570) is 70°C, the size of the optical signal output from the light source drops to 50% compared to the size at 25°C. At this time, if the transmission unit (the first transmission unit 520, the second transmission unit 570) knows the above-described information in advance, in order to increase the size of the optical signal output at 70°C from 50% to 100%, the light source Since information on how much current should be supplied to the device, that is, the compensation current value can be determined, the compensation current value is stored in advance in a lookup table (first reference table 544, second reference table 584). do.

The active optical cable 200 capable of operating in a wide temperature range according to an embodiment of the present invention may control all number of transmission units implemented by an optical link including a plurality of channels based on the above-described method.

8 is a view showing the concept of an optical system included in the assembly for optical transmission and reception according to the present embodiment.

The first transmission/reception module 410 according to the present embodiment may be formed including the first optical assembly 810.

The first optical assembly 810 is an assembly for optical transmission and reception, and a first all-optical conversion element 524 for transmitting an optical signal, a first collimator lens 820, a first reflector 830, and a first transmitter condensing lens unit ( 840). Here, the first transmitter condensing lens unit 840 includes a first condensing lens 842 and a first spacer 844.

The first collimator lens 820 processes light emitted while spreading from at least one first electro-optical conversion element 524 into a first parallel beam having a parallel shape. The first collimator lens 820 transmits the first parallel beam to the first reflector 830. Here, the set of rays is referred to as a beam.

The first reflector 830 changes the traveling direction of the first parallel beam by a preset angle to form a second parallel beam. The first reflector 830 transmits a second parallel beam in which the path of the parallel beam from the first collimator lens 820 is changed by 90° to the first condensing lens 842.

The first condensing lens 842 condenses the second parallel beam and makes it incident to a first end positioned at a predetermined distance.

The thickness of the first spacer 844 in the x direction corresponds to a distance equal to the focal length of the first condensing lens 842. By forming the thickness of the first spacer 844 in the x direction equal to the focal length of the first condensing lens 842, light passing through the first condensing lens 842 may be collected in the core of the optical fiber 850.

When the first optical assembly 810 according to the present embodiment is applied to an optical receiver, the role of the collimator lens and the condensing lens is opposite to that of the lenses applied to the optical transmitter in terms of the functionality of the lens. Hereinafter, a component including several individual functional elements will be referred to as an assembly.

The first optical assembly 810 is an assembly for transmitting and receiving an optical signal, a first photoelectric conversion element 536 for receiving an optical signal, a fourth condensing lens 881, a fourth reflector 871, and a first receiver condensing lens unit ( 861). Here, the first receiver condensing lens unit 861 includes a fourth collimator lens 863 and a fourth spacer 865.

At least one first electro-optical conversion element 524 and at least one first photoelectric conversion element 536 are optically connected to at least one optical link 430 through a first optical assembly 810. The first optical signal is light emitted while spreading from at least one first electro-optical conversion element 524.

The second transmission/reception module 420 according to the present embodiment may be implemented as the second optical assembly 820.

The second optical assembly 820 is an assembly for optical transmission and reception, and a second all-optical conversion element 574 for transmission of an optical signal, a third collimator lens 821, a third reflector 831, and a second transmitter condensing lens unit ( 841). Here, the second transmitter condensing lens unit 841 includes a third condensing lens 832 and a third spacer 845.

The third collimator lens 821 processes the light emitted while spreading from the at least one second electro-optical conversion element 574 into a third parallel beam having a parallel shape. The third collimator lens 821 transmits the third parallel beam to the third reflector 831. Here, the set of rays is referred to as a beam.

The third reflector 831 forms a fourth parallel beam by changing the traveling direction of the third parallel beam by a predetermined angle. The third reflector 831 sends a fourth parallel beam in which the path of the parallel beam from the third collimator lens 821 is changed by 90° to the third condensing lens 832.

The third condensing lens 832 condenses the fourth parallel beam and makes it incident to a second end positioned at a predetermined distance. The third optical signal is light emitted while spreading from at least one second electro-optical conversion element 574.

The thickness of the third spacer 845 in the x direction corresponds to a distance equal to the focal length of the first condensing lens 842. By forming the thickness of the third spacer 845 in the x direction equal to the focal length of the third condensing lens 832, light passing through the third condensing lens 832 may be collected in the core of the optical fiber 851.

When the second optical assembly 820 according to the present embodiment is applied to an optical receiver, the role of the collimator lens and the condensing lens is opposite to that of the lenses applied to the optical transmitter in terms of the functionality of the lens. Hereinafter, a component including several individual functional elements will be referred to as an assembly.

The second optical assembly 820 is an assembly for transmitting and receiving an optical signal, a first photoelectric conversion element 536 for receiving an optical signal, a second condensing lens 880, a second reflector 870, and a second receiver condensing lens unit ( 860). Here, the second receiver condensing lens unit 860 includes a second collimator lens 862 and a second spacer 864.

At least one second electro-optical conversion element 574 and at least one second photoelectric conversion element 562 are optically connected to at least one optical link 430 through a second optical assembly 820.

The above description is merely illustrative of the technical idea of the present embodiment, and those of ordinary skill in the technical field to which the present embodiment pertains will be able to make various modifications and variations without departing from the essential characteristics of the present embodiment. Accordingly, the present embodiments are not intended to limit the technical idea of the present embodiment, but to explain the technical idea, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of this embodiment should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present embodiment.

200: active optical cable (AOC)
202: first host unit 204: second host unit
410: first transmission/reception module 420: second transmission/reception module
430: optical link
320: first transmission unit
502: first electric pad portion 504: second electric pad portion
524: first electro-optical conversion device
526: first transmission circuit 542: first control unit
544: first reference table
530: first receiver
534: first receiving circuit
536: first photoelectric conversion element
560: second receiver
562: second photoelectric conversion element 564: second receiving circuit
572: second transmission circuit 574: second all-optical conversion element
582: second control unit
584: second reference table

Claims (13)

An optical link including a first end and a second end to transmit an optical signal between the first end and the second end in both directions;
Converts the first electrical signal input from the first host unit into a first optical signal and then transmits it from the first end to the second end or converts a second optical signal received from the second end into a second electrical signal A first transmission/reception module configured to output the output to the first host unit and control a magnitude of the first optical signal according to an electro-optical characteristic and temperature previously stored in a first reference table;
Converts a third electrical signal input from the second host unit into a third optical signal, and then transmits it from the second end to the first end or converts a fourth optical signal received from the second end into a fourth electrical signal. And a second transmission/reception module for outputting to the second host unit and controlling the size of the third optical signal according to the electro-optical characteristics and temperature previously stored in the second reference table,
The first transmission/reception module includes the first reference table, the second transmission/reception module includes the second reference table,
The first reference table includes a first input current value that is a bias current value input to the first transmission/reception module, a first output current value output from the second transmission/reception module corresponding to the first input current value, and the first When the output current value is different from the preset first reference value, a first input current compensation value for compensating the first output current value is stored, and
The second reference table includes a second input current value that is a bias current value input to the second transmission/reception module, a second output current value output from the first transmission/reception module corresponding to the second input current value, and the second When the output current value is different from the preset second reference value, a second input current compensation value for compensating the second output current value is stored, and
The first transmission/reception module includes a first temperature sensor configured to detect a first temperature, which is a temperature in a first transmission unit included in the first transmission/reception module, and the first transmission/reception module includes the first temperature sensor according to the change of the first temperature. An input current value, the first output current value, and the first input current compensation value are stored,
The second transmission/reception module includes a second temperature sensor that senses a second temperature, which is a temperature in a second transmission unit included in the second transmission/reception module, and includes the second temperature sensor according to the change of the second temperature in the second reference table. An active optical cable, characterized in that to store an input current value, the second output current value, and the second input current compensation value. The method of claim 1,
The first transmission/reception module,
A first electric pad unit configured to receive the first electric signal from the first host unit or to transmit the second electric signal to the first host unit; A first transmission unit including a first electro-optical conversion element for converting the first electric signal into the first optical signal, and a first transmission circuit for driving the first electro-optical conversion element; And a first receiver having a first photoelectric conversion element for converting the second optical signal into the second electric signal, and a first receiving circuit for driving the first photoelectric conversion element, and
The second transmission/reception module,
A second electric pad unit configured to receive the third electric signal from the second host unit or to transmit the fourth electric signal to the second host unit; A second transmission unit including a second electro-optical conversion element for converting the third electric signal into the third optical signal and a second transmission circuit for driving the second electro-optical conversion element; And a second receiving unit having a second photoelectric conversion element for converting the fourth optical signal into the fourth electric signal, and a second receiving circuit unit for driving the second photoelectric conversion element. The method of claim 2,
The first reference table stores electro-optical characteristics of the second receiving unit and a compensation current value according to temperature, and the second reference table stores electro-optical characteristics of the first receiving unit and a compensation current value according to temperature,
The first transmission unit includes a first control unit for controlling the magnitude of the first optical signal by using a current value corresponding to an electro-optical characteristic and temperature of the second receiving unit among information stored in the first reference table,
The second transmission unit includes a second control unit for controlling the magnitude of the third optical signal by using a current value corresponding to an electro-optical characteristic and temperature of the first receiving unit among information stored in the second reference table. Active optical cable. delete delete The method of claim 1,
The first transmitter uses information previously stored in the first reference table to find a first linear section in which a change in the first output current value changes linearly with respect to a change in the first input current value, and the first The input current value is set to be located at an average value or an intermediate value of the first linear section,
The second transmitter uses information previously stored in the second reference table to find a second linear section in which a change in the second output current value linearly changes with respect to the change in the second input current value, and the second An active optical cable, characterized in that the input current value is set to be located at an average value or an intermediate value of the second linear section. The method of 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 a logic information value of at least two bits per unit clock pulse. An active optical cable, characterized in that it is an optical signal generated based on an Amplitude Modulation) technique. The method of claim 7,
The pulse amplitude modulation technique is an active optical cable, characterized in that including PAM-4, PAM-8 and PAM-16. The method of claim 1,
At least one module of the first transmission/reception module and the second transmission/reception module,
An active optical cable comprising at least one of a retimer and an equalizer. The method of claim 2,
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 transmission unit, and the other end of the at least one optical fiber is connected to the second reception unit. The method of claim 10,
The first electro-optical conversion element and the first photoelectric conversion element are optically connected to at least one optical link through a first optical assembly,
The second electro-optical conversion element and the second photoelectric conversion element are optically connected to the at least one optical link through a second optical assembly. The method of claim 11,
The first optical assembly,
A first collimator lens that processes light emitted while spreading from the first electro-optical conversion element into a first parallel beam in a parallel shape, and a second parallel beam by changing the traveling direction of the first parallel beam by a predetermined angle. A first reflector and a first condensing lens for condensing the second parallel beam to be incident to the first end positioned at a predetermined distance,
The second optical assembly,
A third collimator lens that processes light emitted while spreading from the second electro-optical conversion element into a third parallel beam of a parallel shape, and a fourth parallel beam by changing the traveling direction of the third parallel beam by a predetermined angle. And a third condensing lens configured to condense the fourth parallel beam and enter the second end portion at a predetermined distance. The method of claim 12,
The first optical signal is light emitted while spreading from the first electro-optical conversion element, and the third optical signal is light emitted while being spread from the second electro-optical conversion element.

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