CN117498938A - Optical module transmitting/receiving device, control method, electronic device, and readable storage medium - Google Patents

Abstract

The application is applied to the technical field of optical fiber communication, and discloses an optical module receiving and transmitting device, a control method, an electronic device and a readable storage medium, wherein the optical module receiving and transmitting device is a CSFP optical module, and the CSFP optical module comprises: the driving module is connected with the optical transceiver module; the optical transceiver module comprises a first optical transceiver component and a second optical transceiver component; the first optical transceiver component is used for converting the electric signal sent by the driving module into an optical signal with an uplink wavelength and sending the optical signal with the uplink wavelength, and is also used for converting the received optical signal with the downlink wavelength into an electric signal and sending the electric signal to the driving module; the second optical transceiver component is used for converting the electrical signal sent by the driving module into an optical signal with a downlink wavelength and sending the optical signal with the downlink wavelength, and is also used for converting the received optical signal with the uplink wavelength into the electrical signal and sending the electrical signal to the driving module. The application aims to solve the technical problem that optical fibers of a CSFP optical module are easy to be connected in a wrong way.

Description

Optical module transmitting/receiving device, control method, electronic device, and readable storage medium

Technical Field

The application belongs to the technical field of optical fiber communication, and relates to an optical module receiving and transmitting device, a control method, an electronic device and a readable storage medium.

Background

The CSFP (Compact Small Form-Factor Pluggable) module follows CSFP MSA (Compact Small Form-Factor Pluggable Multi-Source Agreement) protocol, adopts a dual-channel single-fiber bidirectional design, and can support bidirectional data transmission capacity of two channels in a structure with the same packaging size as SFP (Small Form Pluggable, optical interface). The CSFP optical module is composed of two identical BIDI (BIDI) optical modules, and the BIDI optical modules can simultaneously complete the transmission of one wavelength optical signal and the reception of another wavelength optical signal, and the other end is required to complete the reception of one wavelength optical signal and the transmission of another wavelength optical signal to achieve Bidirectional communication, so that the BIDI optical modules must be used in pairs, wherein one BIDI is used as an uplink transmission end, and the other BIDI is used as a downlink transmission end.

Therefore, when using the CSFP optical module, the uplink transmission end and the downlink transmission end need to be distinguished to ensure that the CSFP optical module at the uplink transmission end and the CSFP optical module at the downlink transmission end can realize two-way communication, but because the uplink transmission end and the downlink transmission end are manually distinguished, the optical fiber connection of the CSFP optical module is easy to be wrong, and the use difficulty of the CSFP optical module is further increased.

Disclosure of Invention

The main purpose of the present application is to provide an optical module transceiver, a control method, an electronic device and a readable storage medium, which aim to solve the technical problem of easy error connection of optical fibers of a CSFP optical module.

To achieve the above object, the present application provides an optical module transceiver, including:

the optical module receiving and transmitting device is a CSFP optical module, and the CSFP optical module comprises: the device comprises a driving module and an optical transceiver module, wherein the driving module is connected with the optical transceiver module;

the optical transceiver module comprises a first optical transceiver component and a second optical transceiver component;

the first optical transceiver component is used for converting the electric signal sent by the driving module into an optical signal with an uplink wavelength and sending the optical signal with the uplink wavelength, and is also used for converting the received optical signal with a downlink wavelength into an electric signal and sending the electric signal to the driving module;

The second optical transceiver module is configured to convert an electrical signal sent by the driving module into an optical signal with the downlink wavelength and send the optical signal with the downlink wavelength, and is also configured to convert a received optical signal with the uplink wavelength into an electrical signal and send the electrical signal to the driving module.

In order to achieve the above object, the present application provides an optical module transmitting/receiving control method, which includes:

responding to an electric signal sending instruction of a main control end, wherein a CSFP optical module of the main control end receives the electric signal and converts the electric signal into an optical signal with uplink wavelength or an optical signal with downlink wavelength;

and transmitting the optical signal of the uplink wavelength or the optical signal of the downlink wavelength to a CSFP optical module at the opposite end of the main control end through an optical fiber so as to send the electric signal of the main control end to the opposite end.

The application also provides an electronic device, comprising: the optical module transmission/reception control method comprises a memory, a processor and a program of the optical module transmission/reception control method stored in the memory and capable of running on the processor, wherein the program of the optical module transmission/reception control method can realize the steps of the optical module transmission/reception control method when being executed by the processor.

The present application also provides a readable storage medium, where a program for implementing an optical module transmission/reception control method is stored on the readable storage medium, where the program for implementing the optical module transmission/reception control method implements the steps of the optical module transmission/reception control method described above when executed by a processor.

The present application also provides a computer program product comprising a computer program which, when executed by a processor, implements the steps of the optical module transmit-receive control method as described above.

The application provides an optical module receiving and transmitting device, a control method, an electronic device and a readable storage medium, wherein the optical module receiving and transmitting device is a CSFP optical module, and the CSFP optical module comprises: the device comprises a driving module and an optical transceiver module, wherein the driving module is connected with the optical transceiver module; the optical transceiver module comprises a first optical transceiver component and a second optical transceiver component; the first optical transceiver component is used for converting the electric signal sent by the driving module into an optical signal with an uplink wavelength and sending the optical signal with the uplink wavelength, and is also used for converting the received optical signal with a downlink wavelength into an electric signal and sending the electric signal to the driving module; the second optical transceiver module is configured to convert an electrical signal sent by the driving module into an optical signal with the downlink wavelength and send the optical signal with the downlink wavelength, and is also configured to convert a received optical signal with the uplink wavelength into an electrical signal and send the electrical signal to the driving module.

In a general CSFP optical module, the wavelength of light received by the first optical transceiver module and the wavelength of light received by the second optical transceiver module are the same, that is, the general CSFP optical module only receives an optical signal with one wavelength and transmits an optical signal with another wavelength, so when the general CSFP optical module is used, two different CSFP optical modules are needed to be used, one is a CSFP optical module at an uplink transmission end, the other is a CSFP optical module at a downlink transmission end, where the wavelength of the optical signal received by the CSFP optical module at the uplink transmission end may be an uplink wavelength, the wavelength of the optical signal transmitted by the CSFP optical module at the downlink transmission end is a downlink wavelength, and the wavelength of the optical signal transmitted by the CSFP optical module at the downlink transmission end should be an uplink wavelength, so that bidirectional communication can be realized between the two CSFP optical modules.

The first optical transceiver component of the CSFP optical module can receive the optical signals of the uplink wavelength and transmit the optical signals of the downlink wavelength, and the second optical transceiver component can receive the optical signals of the downlink wavelength and the optical signals of the uplink wavelength, so that the optical signals of two wavelengths can be received on the same CSFP optical module, the optical signals of the two wavelengths can be transmitted, and further, when the CSFP optical module is used, the CSFP optical module is not required to be distinguished to be an uplink transmission end or a downlink transmission end, the CSFP optical module in the application can be directly used when the two-way communication is carried out, and the problem that the optical fibers of the CSFP optical module are misplaced due to the errors of the uplink transmission end and the downlink transmission end can be avoided.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the application and together with the description, serve to explain the principles of the application.

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required to be used in the description of the embodiments or the prior art will be briefly described below, and it will be obvious to those skilled in the art that other drawings can be obtained from these drawings without inventive effort.

Fig. 1 is a schematic structural diagram of an optical module transceiver device of the present application;

fig. 2 is a schematic diagram of cross transmission of an external output signal of a driving module in the optical module transceiver of the present application;

fig. 3 is a schematic diagram of cross transmission of an external input signal of a driving module in the optical module transceiver of the present application;

FIG. 4 is a schematic diagram of cross transmission of the internal output signals of the driving module in the optical module transceiver of the present application;

FIG. 5 is a schematic diagram of cross transmission of an intra-pair input signal of a driving module in an optical module transceiver of the present application;

FIG. 6 is a schematic diagram of a hardware connection between an optical transceiver module and a PCB in a CSFP optical module;

Fig. 7 is a schematic diagram of connection between a master control end and an opposite end of an optical module transceiver device in the present application;

FIG. 8 is a schematic flow chart of an embodiment of a method for transceiving an optical module according to the present application;

fig. 9 is a schematic device structure diagram of a hardware operating environment related to an optical module transceiving control method in an embodiment of the present application.

Reference numerals illustrate:

reference numerals	Name of the name	Reference numerals	Name of the name
				100	CSFP optical module	110	Optical transceiver module
120	Driving module	111	First optical transceiver module
				112	Second optical transceiver module	121	First drive assembly
122	Second drive assembly	200	Main control terminal
				210	First channel of main control end	220	Second channel of main control end
PCB	PCB (printed circuit board)	P1	Flexible board for transmitting end
				P2	Flexible board for receiving end	C1	Optical device

The implementation, functional features and advantages of the present application will be further described with reference to the accompanying drawings in conjunction with the embodiments.

Detailed Description

In order to make the above objects, features and advantages of the present application more comprehensible, the following description will make the technical solutions of the embodiments of the present application clear and complete with reference to the accompanying drawings of the embodiments of the present application. It will be apparent that the described embodiments are only some, but not all, of the embodiments of the present application. All other embodiments, based on the embodiments herein, which are within the scope of the protection of the present application, will be within the purview of one of ordinary skill in the art without the exercise of inventive faculty.

Example 1

Referring to fig. 1, an embodiment of the present application provides an optical module transceiver, where in a first embodiment of the present application, the optical module transceiver includes:

the optical module receiving and transmitting device is a CSFP optical module, and the CSFP optical module comprises: the device comprises a driving module and an optical transceiver module, wherein the driving module is connected with the optical transceiver module;

the optical transceiver module comprises a first optical transceiver component and a second optical transceiver component;

the first optical transceiver component is used for converting the electric signal sent by the driving module into an optical signal with an uplink wavelength and sending the optical signal with the uplink wavelength, and is also used for converting the received optical signal with a downlink wavelength into an electric signal and sending the electric signal to the driving module;

the second optical transceiver module is configured to convert an electrical signal sent by the driving module into an optical signal with the downlink wavelength and send the optical signal with the downlink wavelength, and is also configured to convert a received optical signal with the uplink wavelength into an electrical signal and send the electrical signal to the driving module.

In fig. 1, 100 is a CSFP optical module in the embodiment of the present application, 110 is an optical transceiver module, 111 is a first optical transceiver module, 112 is a second optical transceiver module, 120 is a driving module, TX (Transmit) 1 of the first optical module in fig. 1 refers to a wavelength of a transmitted optical signal being an uplink wavelength 1, rx (receive) 2 refers to a wavelength of a received optical signal being a downlink wavelength 2, TX2 of the second optical module refers to a wavelength of a transmitted optical signal being a downlink wavelength 2, rx1 refers to a wavelength of a received optical signal being an uplink wavelength 1.

It should be noted that, the driving module includes a first driving component and a second driving component, the driving module is configured to receive an external electrical signal of the CSFP optical module, the driving module is configured to send an electrical signal to the outside, the first driving component may be a driving chip Driver, the second driving component may also be a driving chip Driver, the first optical transceiver component is configured to perform photoelectric signal interconversion, the second optical transceiver component is configured to perform photoelectric signal interconversion, the first optical transceiver component and the second optical transceiver component are both optical devices, and the optical devices are BOSA (Bi-Directional Optical Sub-Assembly, light emitting and receiving components). The uplink wavelength is different from the downlink wavelength, the first optical transceiver component can receive the optical signal of the uplink wavelength and transmit the optical signal of the downlink wavelength, and the second optical transceiver component can transmit the optical signal of the uplink wavelength and receive the optical signal of the downlink wavelength.

In the embodiment of the application, the optical signals with two wavelengths can be received on the same CSFP optical module, and the optical signals with two wavelengths can be sent, so that when the CSFP optical module is used, whether the CSFP optical module is an uplink transmission end or a downlink transmission end is not needed to be distinguished, and the CSFP optical module in the application can be directly used when bidirectional communication is carried out, thereby avoiding the problem that the optical fibers of the CSFP optical module are misplaced due to the wrong differentiation of the uplink transmission end and the downlink transmission end. Two identical CSFP optical modules can be used for realizing two-way communication, and the CSFP optical modules are not required to be distinguished as uplink transmission ends or downlink transmission ends, so that the CSFP optical module manufacturers can more conveniently produce the CSFP optical modules, and the CSFP optical modules are more convenient for users to use. Generally, when two-way communication is performed, if a user has a plurality of pairs of CSFP optical modules at an uplink transmission end and CSFP optical modules at a downlink transmission end, if the CSFP optical modules at the uplink transmission end in the plurality of pairs fail or the CSFP optical modules at the downlink transmission end fail, the two-way communication cannot be performed by using the CSFP optical modules.

In addition, the first optical transceiver component only receives downlink wavelength, the second optical transceiver component only receives uplink wavelength, and when the optical fibers are in error connection, signals cannot be transmitted, so that the optical fibers can be timely found out that the optical fibers are in error connection between the two CSFP optical modules, the investigation efficiency when the optical fibers are in error insertion is improved, and the channels can be further guaranteed to be connected correctly.

Further, the driving module is used for cross-transmitting the internal electric signals of the CSFP optical module;

when the CSFP optical module is connected with a main control end, the main control end is connected with the driving module of the CSFP optical module so as to perform signal interaction between the main control end and the CSFP optical module;

the main control end comprises a first channel and a second channel, and the driving module comprises a first driving component and a second driving component;

the driving module is used for cross-transmitting internal electric signals of the CSFP optical module;

the internal electric signal is an external output signal of the driving module, an external input signal of the driving module, an internal input signal of the driving module or an internal output signal of the driving module.

In this embodiment, it should be noted that, the driving module includes a first driving component and a second driving component, where the driving module is configured to cross-transmit an internal electrical signal of the CSFP optical module, and the internal point signal is an external output signal of the driving module, an external input signal of the driving module, an internal input signal of the driving module, or an internal output signal of the driving module. The external output signal of the driving module is an electric signal sent by the driving module to the main control end, and the external input signal of the driving module is an electric signal of the main control end received by the driving module; the in-pair output signal of the driving module is an electric signal sent by the driving module to the optical transceiver module; the input signals of the driving module in pairs are the electric signals of the optical transceiver module received by the driving module.

The external output signal refers to the external transmission electric signal of the CSFP optical module, the external input signal refers to the external electric signal received by the CSFP optical module, the internal output signal refers to the internal transmission electric signal of the drive module of the CSFP optical module, and the internal input signal refers to the internal electric signal received by the drive module of the CSFP optical module, wherein the internal refers to the optical transceiver module.

The application scenario of the CSFP optical module is generally that the first CSFP optical module is electrically connected to the main control end, the first CSFP optical module is connected to the second CSFP optical module through an optical fiber, and the second CSFP optical module is electrically connected to the opposite end of the main control end, so as to realize bidirectional communication between the main control end and the opposite end, where the first CSFP optical module and the second CSFP optical module are both CSFP optical modules in the embodiment of the present application.

When the internal electric signals in the CSFP optical module are transmitted in a cross mode, one signal is transmitted in a cross mode, specifically, when the external output signals are transmitted in a cross mode, the external input signals, the internal input signals and the internal output signals are not transmitted in a cross mode, when the external input signals are transmitted in a cross mode, the external output signals, the external input signals and the internal output signals are not transmitted in a cross mode, when the internal input signals are transmitted in a cross mode, the external output signals, the external input signals and the internal input signals are not transmitted in a cross mode, and when the internal output signals are transmitted in a cross mode, the external output signals, the external input signals and the internal input signals are not transmitted in a cross mode. The purpose of only cross-transmitting one path of signal is to ensure that when the main control end, the first CSFP optical module, the second CSFP optical module and the opposite end are connected during two-path bidirectional communication, the first channel of the main control end and the first channel of the opposite end can perform signal interaction, the second channel of the main control end and the second channel of the opposite end can perform signal interaction, and the problem that the signal is transmitted to the second channel of the opposite end when the first channel of the main control end wants to transmit the signal to the first channel of the opposite end is avoided. The main control end is a switch connected with the driving module of the CSFP optical module, the opposite end is also a switch connected with the driving module of the CSFP optical module, the main control end comprises a first channel and a second channel, and the first channel and the second channel are connected with the driving module.

Further, referring to fig. 2, fig. 2 is a schematic diagram illustrating cross transmission of an external output signal of the driving module, in fig. 2, 200 is a main control end, 210 is a first channel of the main control end, and 220 is a second channel of the main control end.

The external output signal of the driving module is an electric signal sent by the driving module to the main control end;

when the internal electric signals transmitted by the drive module in a crossing way are the external output signals;

the external output end of the first driving component is connected with the input end of the second channel of the main control end so as to control the first driving component to send the electric signal to the second channel;

the external output end of the second driving component is connected with the input end of the first channel of the main control end to control the second driving component to send the electric signal to the first channel;

the external input end of the first driving component is connected with the output end of the first channel of the main control end, and the external input end of the second driving component is connected with the output end of the second channel of the main control end;

the first driving component is connected with the first light receiving and transmitting component, and the second driving component is connected with the second light receiving and transmitting component.

It should be noted that, in general, the signal sent by the driving module to the main control end is an electrical signal sent by the first driving component to the first channel of the main control end, and an electrical signal sent by the second driving component to the second channel of the main control end, referring to fig. 2, the cross transmission of the external output signal is to control the first driving component to send an electrical signal to the second channel of the main control end, and control the second driving component to send an electrical signal to the first channel of the main control end so as to cross-transmit the external output signal of the first driving component and the external output signal of the second driving component. The external output port of the first driving component may be directly disposed on the second driving component, and the external output port of the second driving component may be disposed on the first driving component, so as to realize connection between the external output port of the first driving component and the input end of the second channel of the main control end, and connection between the external output port of the second driving component and the input end of the first channel of the main control end, thereby realizing cross transmission of the external output signal.

In this embodiment, an external input end of the first driving component is connected with an output end of the first channel of the main control end to control the first driving component to receive the electrical signal of the first channel, and an external input end of the second driving component is connected with an output end of the second channel of the main control end to control the second driving component to receive the electrical signal of the second channel. The first driving component is connected with the first optical transceiver component to realize the interaction of electric signals between the first driving component and the first optical transceiver component, and the second driving component is connected with the second optical transceiver component to realize the interaction of electric signals between the second driving component and the second optical transceiver component.

In this embodiment of the present application, since the external output signal of the first driving component and the external output signal of the first driving component are transmitted in a cross manner, and the external input signal of the first driving component and the external input signal of the second driving component are not transmitted in a cross manner, and the driving module and the optical transceiver module are not transmitted in a cross manner, when the first channel of the main control end transmits an electrical signal to the first driving component, the first driving component in the CSFP optical module of the main control end transmits the electrical signal to the first optical transceiver module, the first optical transceiver module converts the electrical signal into an optical signal with an uplink wavelength, the optical signal is transmitted to the second optical transceiver module in the CSFP optical module of the opposite end through the optical fiber, and the second optical transceiver module in the CSFP optical module of the opposite end converts the optical signal into an electrical signal and transmits the electrical signal to the second driving component.

Further, referring to fig. 3, fig. 3 is a schematic diagram of cross transmission of an external input signal of the driving module.

The external input signal of the driving module is an electric signal of the main control end received by the driving module;

when the internal electric signals transmitted by the drive module in a crossing way are the external input signals;

the external input end of the first driving component is connected with the output end of the second channel of the main control end so as to control the first driving component to receive the electric signal of the second channel;

the external input end of the second driving component is connected with the output end of the first channel of the main control end to control the second driving component to receive the electric signal of the first channel;

the external output end of the first driving component is connected with the input end of the first channel of the main control end, and the external output end of the second driving component is connected with the input end of the second channel of the main control end;

the first driving component is connected with the first light receiving and transmitting component, and the second driving component is connected with the second light receiving and transmitting component.

In this embodiment of the present application, it should be noted that, generally, the driving module receives the electrical signal of the main control end and receives the electrical signal of the first channel by the first driving component and receives the electrical signal of the second channel by the second driving component, and in this embodiment of the present application, referring to fig. 3, the cross transmission of the external input signal is to control the first driving component to receive the electrical signal of the second channel and control the second driving component to receive the electrical signal of the first channel, so as to cross transmit the external input signal of the first driving component and the external input signal of the second driving component. For example, the external input end of the first driving component may be directly disposed on the second driving component and the external input end of the second driving component may be disposed on the first driving component, so as to connect the external input end of the first driving component with the output end of the second channel, and the external input end of the second driving component is connected with the output end of the first channel, thereby implementing cross transmission of the external input signal.

In this embodiment, an external output end of the first driving component is connected with an input end of a first channel of the main control end to control the first driving component to send an electrical signal to the first channel, and an external output end of the second driving component is connected with an input end of a second channel of the main control end to control the second driving component to send an electrical signal to the second channel; the first driving component is connected with the first optical transceiver component to realize the interaction of electric signals between the first driving component and the first optical transceiver component, and the second driving component is connected with the second optical transceiver component to realize the interaction of electric signals between the second driving component and the second optical transceiver component.

In the embodiment of the application, the external input signal of the first driving component and the external input signal of the first driving component are transmitted in a cross manner, and the external output signal of the first driving component and the external output signal of the second driving component are not transmitted in a cross manner, and the driving module and the optical transceiver module are not transmitted in a cross manner. Taking the signal transmitted by the second channel as an example, the signal transmission process from the main control end to the opposite end is described, when the first driving component receives the electric signal transmitted by the second channel, the first driving component in the CSFP optical module of the main control end converts the electric signal into an optical signal with a downlink wavelength, the optical signal with the downlink wavelength is transmitted to the second optical transceiver component of the CSFP optical module of the main control end-to-end through optical fiber, the second optical transceiver component converts the optical signal with the downlink wavelength into the electric signal and transmits the electric signal to the second driving module, and the second driving module transmits the electric signal to the second channel of the main control end-to-end to realize signal transmission between the second channel of the main control end and the second channel of the opposite end, while the first channel of the non-main control end and the second channel of the opposite end perform signal transmission. Correspondingly, the second channel of the opposite end can also send an electric signal to the second channel of the main control end, and the first channel of the opposite end can also send an electric signal to the first channel of the main control end. In the embodiment of the application, the first channel of the main control end and the first channel of the opposite end can realize signal interaction, and the second channel of the main control end and the second channel of the opposite end can also realize signal interaction.

Further, referring to fig. 4, fig. 4 is a schematic diagram of cross transmission of the pair of internal output signals of the driving module.

The in-pair output signal of the driving module is an electric signal sent by the driving module to the optical transceiver module;

when the internal electric signals transmitted by the drive modules in a crossing way are the pair of internal output signals;

the in-pair output end of the first driving component is connected with the electric signal input end of the second optical transceiver component so as to control the first driving component to send the electric signal to the second optical transceiver component;

the in-pair output end of the second driving assembly is connected with the electric signal input end of the first optical transceiver assembly to control the second driving assembly to send the electric signal to the first optical transceiver assembly;

the in-pair input end of the first driving assembly is connected with the electric signal output end of the first optical transceiver assembly, and the in-pair input end of the second driving assembly is connected with the electric signal output end of the second optical transceiver assembly;

the first driving component is connected with the first channel, and the second driving component is connected with the second channel.

In the conventional CSFP optical module, the first driving module performs electrical signal interaction with the first optical transceiver, and the second driving module performs electrical signal interaction with the second optical transceiver. In the embodiment of the present application, when the internal electrical signal is an internal output signal, referring to fig. 4, the internal output signal of the cross transmission driving module is an electrical signal sent from the internal output end of the first driving module to the second optical transceiver module, and an electrical signal is sent from the internal output end of the second driving module to the first optical transceiver module, so as to implement cross transmission of the internal output signal.

In this embodiment, the in-pair input end of the first driving component is connected with the electrical signal output end of the first optical transceiver component to control the first driving component to receive the electrical signal of the first optical transceiver component, and the in-pair input end of the second driving component is connected with the electrical signal output end of the second optical transceiver component to control the second driving component to receive the electrical signal of the second optical transceiver component. The first driving assembly is connected with the first channel to control signal interaction between the first driving assembly and the first channel, and the second driving assembly is connected with the second channel to control signal interaction between the first driving assembly and the second channel.

In this embodiment of the present application, since the in-pair output signal of the first driving component and the in-pair output signal of the second driving component are cross-transmitted, the in-pair input signal of the first driving component and the in-pair input signal of the second driving component are not cross-transmitted, and the driving module does not cross-transmit when transmitting the signals to the outside. Taking the example that the second driving component receives the electric signal of the second channel, the transmission flow of the electric signal between the main control end and the opposite end is described, the second driving component sends the electric signal to the first optical transceiver component, the first optical transceiver component converts the electric signal into an optical signal with uplink wavelength, the optical signal with uplink wavelength is transmitted to the second optical transceiver component of the CSFP optical module of the opposite end through the optical fiber, the second optical transceiver component of the opposite end converts the optical signal into the electric signal and sends the electric signal to the second driving module of the opposite end so as to send the electric signal to the second channel of the opposite end, and therefore signal transmission between the second channel of the main control end and the second channel of the opposite end is achieved. In the embodiment of the application, the transmission of the limit number between the first channel of the main control end and the first channel of the opposite end can also be realized.

Further, referring to fig. 5, fig. 5 is a schematic diagram of cross transmission of the intra-pair input signals of the driving module.

The input signals in the pair of the driving module are the electric signals of the optical transceiver module received by the driving module;

when the internal electric signals transmitted by the drive modules in a crossing way are the pair of internal input signals;

the in-pair input end of the first driving component is connected with the electric signal output end of the second optical transceiver component so as to control the first driving component to receive the electric signal of the second optical transceiver component;

the pair of inner input ends of the second driving component are connected with the electric signal output end of the first optical transceiver component so as to control the second driving component to receive the electric signal of the first optical transceiver component;

the pair of inner output ends of the first driving component are connected with the electric signal input end of the first optical transceiver component, and the pair of inner output ends of the second driving component are connected with the electric signal input end of the second optical transceiver component;

the first driving component is connected with the first channel of the main control end, and the second driving component is connected with the second channel of the main control end.

In this embodiment, it should be noted that, when the internal electrical signal cross-transmitted by the driving module is the intra-pair input signal, referring to fig. 5, the cross-transmission intra-pair input signal is an electrical signal received by the intra-pair input terminal of the first driving module and an electrical signal received by the intra-pair input terminal of the second driving module, so as to implement cross-transmission of the intra-pair input signal.

In this embodiment, when the internal electrical signal cross-transmitted by the driving module is the intra-pair input signal, the intra-pair output end of the first driving component is connected with the intra-pair input end of the first optical transceiver component to control the first driving component to send an electrical signal to the first optical transceiver component, and the intra-pair output end of the second driving component is connected with the intra-pair input end of the second optical transceiver component to control the second driving component to send an electrical signal to the second optical transceiver component; the first driving assembly is connected with the first channel to control signal interaction between the first driving assembly and the first channel, and the second driving assembly is connected with the second channel to control signal interaction between the first driving assembly and the second channel.

In this embodiment of the present application, since the in-pair input signal of the first driving component and the in-pair input signal of the second driving component are cross-transmitted, and the in-pair output signal of the first driving component and the in-pair output signal of the second driving component are not cross-transmitted, and the driving module does not cross-transmit when transmitting signals externally, the first channel of the main control end is connected to the first driving module, the second channel of the main control end is connected to the second driving module, the CSFP optical module of the main control end is connected to the CSFP optical module of the opposite end, and when the first channel of the opposite end is connected to the first driving component of the CSFP optical module of the opposite end, the signal bidirectional transmission is performed between the first channel of the main control end and the first channel of the opposite end, and the signal bidirectional transmission is performed between the second channel of the main control end and the second channel of the opposite end. Taking the electrical signal of the first channel of the main control end received by the first driving component as an example, explaining the relation of signal transmission between the main control end and the opposite end, the first driving component of the main control end sends the electrical signal to the first optical transceiver component of the CSFP optical module of the main control end, the first optical transceiver component converts the electrical signal into an optical signal with uplink wavelength, the optical signal is sent to the second optical transceiver component of the CSFP optical module of the opposite end through an optical fiber, and the second optical transceiver component converts the optical signal into the electrical signal and sends the electrical signal to the first driving component of the CSFP optical module of the opposite end so as to send the electrical signal to the first channel of the opposite end, thereby realizing signal transmission between the first channel of the main control end and the first channel of the opposite end.

Further, in this embodiment of the present application, the CSFP optical module adopts a single PCB design, referring to fig. 6, fig. 6 is a schematic diagram of hardware connection between an optical transceiver module and a PCB board in the CSFP optical module, in fig. 6, the PCB is a PCB board, P1 is a transmitting end compliance board of an optical device BOSA, P2 is a receiving end compliance board of the optical device BOSA, C1 is an optical device, the optical device is BOSA, both the first optical component and the second optical component may be the optical device BOSA, the optical device shown in fig. 6 is a hardware schematic diagram of the first optical component and the second optical component, the first optical transceiver component and the second optical transceiver component in the CSFP optical module may be interconnected with the PCB board through a flexible circuit board, specifically, the optical transmitting end of the first optical transceiver component and the optical transmitting end of the second optical transceiver component are jointly interconnected with the PCB board, that is, the optical transmitting end compliance board and interconnection are also adopted by the optical transmitting end compliance board, the optical receiving end of the first optical transceiver component and the second optical transceiver component are interconnected with the PCB board, so that the optical receiving end and the optical transceiver module are more simply designed to be interconnected with the receiving end of the PCB board.

Example two

Further, referring to fig. 7, an embodiment of the present application further provides an optical module transmitting/receiving control method, where the optical module transmitting/receiving method includes:

step S10, responding to an electric signal sending instruction of a main control end, wherein a CSFP optical module of the main control end receives the electric signal and converts the electric signal into an optical signal of an uplink wavelength or an optical signal of a downlink wavelength;

step S20, transmitting the optical signal of the uplink wavelength or the optical signal of the downlink wavelength to the CSFP optical module at the opposite end of the master control end through an optical fiber, so as to send the electrical signal of the master control end to the opposite end.

In this embodiment of the present application, it should be noted that, the main control end is connected with the CSFP optical module, when the main control end needs to send an electrical signal, the CSFP optical module of the main control end will respond to the electrical signal sending instruction of the main control end, convert the electrical signal into an optical signal, and transmit the optical signal to the CSFP optical module of the main control end-to-end through the optical fiber, so as to realize that the electrical signal of the main control end is transmitted to the opposite end. The CSFP optical module of the opposite end has the same structure as the CSFP optical module of the main control end. The main control end is provided with a first channel and a second channel, the opposite end is also provided with a first channel and a second channel, the first channel and the second channel of the main control end can both transmit or receive electric signals, the first channel and the second channel of the opposite end can both receive or transmit electric signals, after the main control end and the opposite end are connected through two CSFP optical modules and optical fibers, the first channel of the main control end and the first channel of the opposite end can realize bidirectional signal transmission, and the second channel of the main control end and the second channel of the opposite end can realize bidirectional signal transmission.

In the embodiment of the application, the CSFP optical modules connected with the main control end and the opposite end both receive or transmit optical signals of uplink wavelength and downlink wavelength, so that the uplink transmission end and the downlink transmission end of the CSFP optical module are not required to be distinguished, bidirectional data transmission can be realized by using the same CSFP optical module between the main control end and the opposite end, the usability of the CSFP optical module is improved, and the probability of optical fiber errors is reduced.

Further, the step of receiving an electrical signal by the CSFP optical module at the master control end and converting the electrical signal into an optical signal with an uplink wavelength or an optical signal with a downlink wavelength includes:

step S11, if the first optical transceiver module of the CSFP optical module of the master end receives the electric signal, the electric signal is converted into an optical signal with uplink wavelength;

step S12, if the second optical transceiver module of the CSFP optical module at the master control end receives the electrical signal, the electrical signal is converted into an optical signal with a downlink wavelength.

In this embodiment of the present application, it should be noted that, in the CSFP optical module, the first optical transceiver component transmits an optical signal with an uplink wavelength, the first optical transceiver component receives an optical signal with a downlink wavelength, the second optical transceiver component transmits an optical signal with a downlink wavelength, and the second optical transceiver component receives an optical signal with an uplink wavelength. Therefore, when the first optical transceiver module converts the electrical signal into an optical signal with an uplink wavelength, the optical signal with the uplink wavelength is transmitted through the optical fiber, and the optical signal with the uplink wavelength can be received by the second optical transceiver module of the opposite-end CSFP optical module, because the first optical transceiver module only receives the optical signal with the downlink wavelength, the second optical transceiver module only receives the optical signal with the uplink wavelength, if the optical fiber is connected between the two CSFP optical modules in error, because the first optical transceiver module only receives the downlink wavelength, the second optical transceiver module only receives the uplink wavelength, when the optical fiber is connected in error, the signal can not be transmitted, and further, the optical fiber can be timely found that the optical fiber is connected in error between the two CSFP optical modules, and the investigation efficiency when the optical fiber is connected in error is improved.

For better understanding of the present application, referring to fig. 8, a relationship of signal bidirectional transmission between a main control end and an opposite end is described by taking cross transmission of an external output signal of a driving module in a CSFP optical module as an example. In fig. 8, the output end of the first channel of the master end is connected with the external input end of the first driving component of the CSFP optical module of the master end, and the input end of the first channel of the master end is connected with the external output end of the first driving component of the CSFP optical module of the master end; the output end of the second channel of the main control end is connected with the external input end of the second driving component of the CSFP optical module of the main control end, and the input end of the second channel of the main control end is connected with the external output end of the first driving component of the CSFP optical module of the main control end. Because the cross transmission signal in the CSFP optical module is an external output signal, the external output end of the first driving component and the external output end of the second driving component are exchanged in the CSFP optical module, when the opposite end of the main control end is connected with the CSFP optical module, the input end of the first channel of the opposite end is also the external output end of the second driving component connected with the CSFP optical module, the output end of the first channel of the opposite end is also the external input end of the first driving component connected with the CSFP optical module, the input end of the second channel of the opposite end is connected with the external input end of the first driving component of the CSFP optical module, the output end of the second channel of the opposite end is connected with the external input end of the second driving component of the CSFP optical module, and because the wavelength of the optical signal transmitted by the first optical transceiver component is uplink wavelength 1, the wavelength of the optical signal transmitted by the second optical transceiver component is downlink wavelength 2, the wavelength of the optical signal received by the second optical transceiver component is uplink wavelength 1, so that the optical signals can be transmitted between the optical signals, the opposite ends of the first channel and the second channel of the opposite end are mutually connected with the CSFP optical module, the second channel of the opposite end of the main control end is mutually, the second channel of the opposite end is mutually connected with the second optical transceiver component, and the second channel of the second optical transceiver component is mutually opposite to the second channel, and the opposite end of the CSFP optical module is mutually connected with the second channel, and the second channel of the opposite end of the main control module is mutually opposite, and the second channel is mutually opposite and mutually opposite. In fig. 8, the arrow direction indicates the direction of signal transmission, where, taking an example of sending an electrical signal from the second channel of the main control end to the second driving component, a signal transmission flow of an electrical signal sent from the second channel of the main control end to the second driving component is described, where the second driving component of the CSFP optical module of the main control end receives an electrical signal from the second channel of the main control end, the second driving component sends the electrical signal to the second optical transceiver component, the second optical transceiver component converts the electrical signal into an optical signal with a downlink wavelength, and the optical signal with the downlink wavelength is sent to the first optical transceiver component of the CSFP optical module of the opposite end through an optical fiber between the second optical transceiver component of the CSFP optical module of the main control end and the first optical transceiver component of the CSFP optical module of the opposite end, so that the first driving component of the CSFP optical module of the opposite end sends the electrical signal to the second channel of the opposite end, and the same second channel of the opposite end can also send the electrical signal to the second channel of the opposite end, so that bidirectional transmission of the electrical signal can be achieved.

Example III

The embodiment of the application provides an electronic device, which may be a playing device, including: at least one processor; and a memory communicatively coupled to the at least one processor; the memory stores instructions executable by the at least one processor, and the instructions are executed by the at least one processor, so that the at least one processor can execute the optical module transceiving control method in the above embodiment.

Referring now to fig. 9, a schematic diagram of an electronic device suitable for use in implementing embodiments of the present disclosure is shown. The electronic devices in the embodiments of the present disclosure may include, but are not limited to, mobile terminals such as mobile phones, notebook computers, digital broadcast receivers, PDAs (personal digital assistant, personal digital assistants), PADs (portable Android device, tablet computers), PMPs (Portable Media Player, portable multimedia players), vehicle terminals (e.g., car navigation terminals), and the like, and stationary terminals such as digital TVs, desktop computers, and the like. The electronic device shown in fig. 9 is only one example and should not be construed as limiting the functionality and scope of use of the disclosed embodiments.

As shown in fig. 9, the electronic device may include a processing device 1001 (e.g., a central processor, a graphics processor, or the like) that can perform various appropriate actions and processes according to a program stored in a ROM (Read-Only Memory) 1002 or a program loaded from a storage device 1003 into a RAM (Random Access Memory ) 1004. In the RAM1004, various programs and data required for the operation of the electronic apparatus are also stored. The processing device 1001, the ROM1002, and the RAM1004 are connected to each other by a bus 1005. An input/output (I/O) interface 1006 is also connected to the bus.

In general, the following systems may be connected to the I/O interface 1006: input devices 1007 including, for example, a touch screen, touchpad, keyboard, mouse, image sensor, microphone, tachometer, gyroscope, and the like; an output device 1008 including, for example, an LCD (Liquid Crystal Display ), a speaker, a vibrator, and the like; storage device 1003 including, for example, a magnetic tape, a hard disk, and the like; and communication means 1009. The communication device may allow the electronic device to communicate wirelessly or by wire with other devices to exchange data. While the figures illustrate electronic devices having various systems, it is to be understood that not all illustrated systems are required to be implemented or provided. More or fewer systems may alternatively be implemented or provided.

In particular, according to embodiments of the present disclosure, the processes described above with reference to flowcharts may be implemented as computer software programs. For example, embodiments of the present disclosure include a computer program product comprising a computer program embodied on a computer readable medium, the computer program comprising program code for performing the method shown in the flowcharts. In such an embodiment, the computer program may be downloaded and installed from a network through a communication system, or installed from a storage system, or installed from ROM. The above-described functions defined in the methods of the embodiments of the present disclosure are performed when the computer program is executed by a processing system.

The electronic device provided by the application adopts the optical module receiving and transmitting control method in the first embodiment to solve the technical problem of low robot operation precision caused by the weight change of the end load. Compared with the prior art, the beneficial effects of the product flow data distribution provided by the embodiment of the application are the same as those of the optical module receiving and transmitting control method provided by the embodiment, and other technical features in the optical module receiving and transmitting device are the same as those disclosed by the embodiment method, and are not repeated herein.

It should be understood that portions of the present disclosure may be implemented in hardware, software, firmware, or a combination thereof. In the description of the above embodiments, particular features, structures, materials, or characteristics may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing is merely specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the present application, and the changes and substitutions are intended to be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Example IV

The present embodiment provides a readable storage medium having computer readable program instructions stored thereon for executing the optical module transmission/reception control method in the above embodiment.

The readable storage medium provided in the embodiments of the present application may be, for example, a usb disk, but is not limited to, an apparatus, a device or a device of electric, magnetic, optical, electromagnetic, infrared, or semiconductor, or a combination of any of the above. More specific examples of the readable storage medium may include, but are not limited to: an electrical connection having one or more wires, a portable computer diskette, a hard disk, a Random Access Memory (RAM), a read-only memory (ROM), an erasable programmable EPROM (Electrical Programmable Read Onl y Memory, read-only memory) or flash memory, an optical fiber, a portable compact disc CD-ROM (compact disc read-only memory), an optical storage device, a magnetic storage device, or any suitable combination of the foregoing. In this embodiment, the readable storage medium may be any tangible medium that can contain, or store a program for use by or in connection with an instruction execution apparatus, device, or device. Program code embodied on a readable storage medium may be transmitted using any appropriate medium, including but not limited to: electrical wires, fiber optic cables, RF (radio frequency), and the like, or any suitable combination of the foregoing.

The readable storage medium may be contained in an electronic device; or may exist alone without being assembled into an electronic device.

The readable storage medium carries one or more programs that, when executed by an electronic device, cause the electronic device to: responding to an electric signal sending instruction of a main control end, wherein a CSFP optical module of the main control end receives the electric signal and converts the electric signal into an optical signal with uplink wavelength or an optical signal with downlink wavelength; and transmitting the optical signal of the uplink wavelength or the optical signal of the downlink wavelength to a CSFP optical module at the opposite end of the main control end through an optical fiber so as to send the electric signal of the main control end to the opposite end.

Computer program code for carrying out operations of the present disclosure may be written in one or more programming languages, including an object oriented programming language such as Java, smalltalk, C ++ and conventional procedural programming languages, such as the "C" programming language or similar programming languages. The program code may execute entirely on the user's computer, partly on the user's computer, as a stand-alone software package, partly on the user's computer and partly on a remote computer or entirely on the remote computer or server. In the case of a remote computer, the remote computer may be connected to the user's computer through any kind of network, including a LAN (local area network ) or WAN (Wide Area Network, wide area network), or it may be connected to an external computer (for example, through the Internet using an Internet service provider).

The flowcharts and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of devices, methods and computer program products according to various embodiments of the present application. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based devices which perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

The modules described in the embodiments of the present disclosure may be implemented in software or hardware. Wherein the name of the module does not constitute a limitation of the unit itself in some cases.

The readable storage medium provided by the application is stored with computer readable program instructions for executing the optical module receiving and transmitting control method, and aims to solve the technical problem of low robot operation precision caused by weight change of end load. Compared with the prior art, the beneficial effects of the readable storage medium provided by the embodiment of the present application are the same as the beneficial effects of the optical module receiving and transmitting control method provided by the above embodiment, and are not described in detail herein.

Example five

The present application also provides a computer program product comprising a computer program which, when executed by a processor, implements the steps of the optical module transmit-receive control method as described above.

The application provides a computer program product which aims at solving the technical problem that the working accuracy of a robot is not high due to the weight change of an end load. Compared with the prior art, the beneficial effects of the computer program product provided by the embodiment of the present application are the same as the beneficial effects of the optical module receiving and transmitting control method provided by the above embodiment, and are not described in detail herein.

The foregoing description is only of the preferred embodiments of the present application and is not intended to limit the scope of the claims, and all equivalent structures or equivalent processes using the descriptions and drawings of the present application, or direct or indirect application in other related technical fields are included in the scope of the claims.

Claims (10)

1. An optical module transceiver, characterized in that, the optical module transceiver is a CSFP optical module, the CSFP optical module includes: the device comprises a driving module and an optical transceiver module, wherein the driving module is connected with the optical transceiver module;

the optical transceiver module comprises a first optical transceiver component and a second optical transceiver component;

the first optical transceiver component is used for converting the electric signal sent by the driving module into an optical signal with an uplink wavelength and sending the optical signal with the uplink wavelength, and is also used for converting the received optical signal with a downlink wavelength into an electric signal and sending the electric signal to the driving module;

the second optical transceiver module is configured to convert an electrical signal sent by the driving module into an optical signal with the downlink wavelength and send the optical signal with the downlink wavelength, and is also configured to convert a received optical signal with the uplink wavelength into an electrical signal and send the electrical signal to the driving module.

2. The optical module transceiver of claim 1, wherein when the CSFP optical module is connected to a master control end, the master control end is connected to the driving module of the CSFP optical module to perform signal interaction between the master control end and the CSFP optical module;

The main control end comprises a first channel and a second channel, and the driving module comprises a first driving component and a second driving component;

the driving module is used for cross-transmitting internal electric signals of the CSFP optical module;

the internal electric signal is an external output signal of the driving module, an external input signal of the driving module, an internal input signal of the driving module or an internal output signal of the driving module.

3. The optical module transceiver of claim 2, wherein the external output signal of the driving module is an electrical signal sent by the driving module to the master control terminal;

when the internal electric signals transmitted by the drive module in a crossing way are the external output signals;

the external output end of the first driving component is connected with the input end of the second channel of the main control end so as to control the first driving component to send the electric signal to the second channel;

the external output end of the second driving component is connected with the input end of the first channel of the main control end to control the second driving component to send the electric signal to the first channel;

the external input end of the first driving component is connected with the output end of the first channel of the main control end, and the external input end of the second driving component is connected with the output end of the second channel of the main control end;

The first driving component is connected with the first light receiving and transmitting component, and the second driving component is connected with the second light receiving and transmitting component.

4. The optical module transceiver of claim 2, wherein the external input signal of the driving module is an electrical signal of the master control end received by the driving module;

when the internal electric signals transmitted by the drive module in a crossing way are the external input signals;

the external input end of the first driving component is connected with the output end of the second channel of the main control end so as to control the first driving component to receive the electric signal of the second channel;

the external input end of the second driving component is connected with the output end of the first channel of the main control end to control the second driving component to receive the electric signal of the first channel;

the external output end of the first driving component is connected with the input end of the first channel of the main control end, and the external output end of the second driving component is connected with the input end of the second channel of the main control end;

the first driving component is connected with the first light receiving and transmitting component, and the second driving component is connected with the second light receiving and transmitting component.

5. The optical module transceiver of claim 2, wherein the in-pair output signal of the driving module is an electrical signal sent by the driving module to the optical transceiver module;

when the internal electric signals transmitted by the drive modules in a crossing way are the pair of internal output signals;

the in-pair output end of the first driving component is connected with the electric signal input end of the second optical transceiver component so as to control the first driving component to send the electric signal to the second optical transceiver component;

the in-pair output end of the second driving assembly is connected with the electric signal input end of the first optical transceiver assembly to control the second driving assembly to send the electric signal to the first optical transceiver assembly;

the in-pair input end of the first driving assembly is connected with the electric signal output end of the first optical transceiver assembly, and the in-pair input end of the second driving assembly is connected with the electric signal output end of the second optical transceiver assembly;

the first driving component is connected with the first channel, and the second driving component is connected with the second channel.

6. The optical module transceiver of claim 2, wherein the intra-pair input signal of the driving module is an electrical signal of the optical transceiver module received by the driving module;

When the internal electric signals transmitted by the drive modules in a crossing way are the pair of internal input signals;

the in-pair input end of the first driving component is connected with the electric signal output end of the second optical transceiver component so as to control the first driving component to receive the electric signal of the second optical transceiver component;

the pair of inner input ends of the second driving component are connected with the electric signal output end of the first optical transceiver component so as to control the second driving component to receive the electric signal of the first optical transceiver component;

the pair of inner output ends of the first driving component are connected with the electric signal input end of the first optical transceiver component, and the pair of inner output ends of the second driving component are connected with the electric signal input end of the second optical transceiver component;

the first driving component is connected with the first channel of the main control end, and the second driving component is connected with the second channel of the main control end.

7. The optical module receiving and transmitting control method is characterized by comprising the following steps:

responding to an electric signal sending instruction of a main control end, wherein a CSFP optical module of the main control end receives the electric signal and converts the electric signal into an optical signal with uplink wavelength or an optical signal with downlink wavelength;

And transmitting the optical signal of the uplink wavelength or the optical signal of the downlink wavelength to a CSFP optical module at the opposite end of the main control end through an optical fiber so as to send the electric signal of the main control end to the opposite end.

8. The optical module receiving and transmitting control method according to claim 7, wherein the step of the CSFP optical module at the master end receiving an electrical signal and converting the electrical signal into an optical signal at an uplink wavelength or an optical signal at a downlink wavelength includes:

if the first optical transceiver component of the CSFP optical module of the main control end receives the electric signal, converting the electric signal into an optical signal with uplink wavelength;

and if the second optical transceiver component of the CSFP optical module of the master control end receives the electric signal, converting the electric signal into an optical signal with a downlink wavelength.

9. An electronic device, the electronic device comprising:

at least one processor;

and a memory communicatively coupled to the at least one processor;

wherein the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the steps of the light module transceiving control method according to any of claims 7 to 8.

10. A readable storage medium, wherein a program for implementing an optical module transmission/reception control method is stored on the readable storage medium, and the program for implementing the optical module transmission/reception control method is executed by a processor to implement the steps of the optical module transmission/reception control method according to any one of claims 7 to 8.