DE202019103754U1 - HDMI connection device for an active optical fiber cable - Google Patents

Abstract

An HDMI cable connecting device for an active optical fiber cable, comprising a transmitting section, a receiving section, a fiber optic cable and a power supply module, wherein the power supply module supplies power to the transmitting section and the receiving section, the transmitting section comprising a signal input module and an electro-optical converter module, while the receiving section is a photoelectric Transducer module and has a signal receiving module, and wherein the signal input module for inputting electrical digital signals in the electro-optical converter module, while the electro-optical converter module converts the digital electrical signals into light signals, and wherein the converted light signals are forwarded by means of the optical fiber cable to the photoelectric converter module, while the photoelectric Converter module converts the light signals into the digital electrical signals, wherein the signal receiving module ensures that through the photo electrical converter module to receive converted digital signals.

Description

The invention relates to an HDMI connection device for an active optical fiber cable.

HDMI (High Definition Multimedia Interface) is an interface technology for the transmission of digital video / audio signals, where an HDMI connection transmits uncompressed, high-resolution video data and multichannel audio data with a high quality and a maximum data transfer rate of 18 Gbps, without a Digital-to-analog conversion or analog-to-digital conversion is required before a signal transmission, whereby a video and audio signal transmission of the highest quality is ensured. The disadvantage, however, is that a conventional HDMI connection device causes high manufacturing costs due to its complicated structure.

The invention has for its object to provide an HDMI connection device for an active optical fiber, which avoids the above-mentioned disadvantages by simple measures.

This object is achieved by an HDMI connection device for an active optical waveguide having the features specified in claim 1. Further advantageous developments of the invention will become apparent from the dependent claims.

According to the invention there is provided an HDMI fiber optic cable connection apparatus comprising a transmitter section, a receiver section, a fiber optic cable, and a power module, the power module energizing the transmitter section and the receiver section, the transmitter section having a signal input module and an electro-optic converter module while the receiving section has a photoelectric conversion module and a signal receiving module, and wherein the signal input module inputs electrical digital signals to the electrooptical conversion module while the electrooptical conversion module converts the digital electrical signals into light signals, and wherein the converted light signals are coupled to the photoelectric conversion module by the optical fiber cable be forwarded while the photoelectric conversion module converts the light signals into the digital electrical signals, wherein the signal receiving module ensures to receive the converted by the photoelectric conversion module digital signals.

According to the invention, the signal input module is a first single chip with the model designation "Y51S019P", wherein the electro-optical converter module is a VCSEL driver chip, and wherein the signal receiving module is a second single chip with the model designation "Y51S019P "And wherein the photoelectric conversion module is a PIN_PD driver chip, and wherein the first die, the VCSEL driver chip, the PIN_PD driver chip are electrically connected together, and wherein the second die is electrically connected to the PIN_PD driver chip ,

According to the invention, a bias and impedance matching module is connected between the first single chip and the VCSEL driver chip.

According to the invention, a resonant frequency adjustment module is connected between the PIN_PD driver chip and the second single chip.

According to the invention, the signal input module is electrically connected to the signal receiving module, the signal input module being further connected to a first control switch and a first LED module, wherein the signal input module is configured to send a power signal to the signal receiving module and wherein the signal receiving module is configured in that a high level signal is to be sent to the signal input module after receiving the power signal, and wherein the signal input module is configured so that after receiving the high level signal, a control signal can be sent to the first control switch, and wherein the first Control switch is configured so that the control signal for controlling the operation of the first LED module is to be received.

According to the invention, the signal receiving module is sequentially connected to a second control switch and a second LED light module, wherein the signal receiving module is configured to receive a digital electrical signal and then to send a control signal to the second control switch, and wherein the second control switch is configured such that the second LED light module is actuated after the control signal has been received.

According to the invention, the optical fiber cable is covered with a spiral-shaped elastic metal sleeve in which an electrical conductor cable connecting the signal input module and the signal receiving module and a filling material preventing sliding movement of the optical fiber cable and the electrical conductor cable with respect to the spiral elastic metal sleeve are arranged.

According to the invention, the filling material is made of Kevlar fibers from DuPont, wherein the Kevlar fibers along a longitudinal direction of the spiral-shaped elastic metal sleeve are arranged.

In comparison with the prior art, the HDMI connection device according to the invention has the following advantages:

The HDMI connection device according to the invention for an active optical fiber cable has a simple structure, which leads to low production costs. In the HDMI connection device according to the invention, a cable armor is used which secures or protects against damage by tearing, scratching or squeezing of an optical fiber cable and an electrical conductor cable, thereby increasing the reliability of the product. After the HDMI connection device according to the invention is connected on both sides to corresponding devices, it can be seen directly through a display surface, whether the current signal and corresponding data signals are successfully transmitted, which not only facilitates the monitoring and maintenance, but also increases the assembly efficiency. As a result, a stable data transmission is realized by the optical waveguide cable, without fear that the data transmission is affected by a power failure or a lack of power of a particular channel.

• 1 ein schematisches Diagramm einer erfindungsgemäßen Schaltung;
• 2 ein Schaltbild eines erfindungsgemäßen Signaleingangsmoduls;
• 3 ein Schaltbild eines erfindungsgemäßen, elektrooptischen Wandlermodul;
• 4 ein Schaltbild eines erfindungsgemäßen, fotoelektrischen Wandlermoduls;
• 5 ein Schaltbild eines erfindungsgemäßen Signalempfangsmoduls;
• 6 ein Schaltbild eines ersten Steuerschalters und eines ersten LED-Moduls gemäß der vorliegenden Erfindung;
• 7 ein Schaltbild eines zweiten Steuerschalters und eines zweiten LED-Moduls gemäß der vorliegenden Erfindung;
• 8 ein Schaltbild eines erfindungsgemäßen Stromversorgungsmoduls;
• 9 eine strukturelle Ansicht eines gepanzerten Lichtwellenleiterkabels gemäß der vorliegenden Erfindung;
• 10 einen Schnitt entlang der Linie A-A in 2; und
• 11 einen Schnitt durch ein weiteres gepanzertes Lichtwellenleiterkabel.

In the following the invention and its embodiments will be explained in more detail with reference to the drawing. In the drawing shows:

• 1 a schematic diagram of a circuit according to the invention;
• 2 a circuit diagram of a signal input module according to the invention;
• 3 a circuit diagram of an inventive electro-optical converter module;
• 4 a circuit diagram of a photoelectric converter module according to the invention;
• 5 a circuit diagram of a signal receiving module according to the invention;
• 6 a circuit diagram of a first control switch and a first LED module according to the present invention;
• 7 a circuit diagram of a second control switch and a second LED module according to the present invention;
• 8th a circuit diagram of a power supply module according to the invention;
• 9 a structural view of an armored optical fiber cable according to the present invention;
• 10 a section along the line AA in 2 ; and
• 11 a section through another armored fiber optic cable.

As in 1 1, an active fiber optic cable HDMI connecting apparatus according to the present invention comprises a transmitting section, a receiving section, a fiber optic cable, and a power supply module that supplies power to the transmitting section and the receiving section, the transmitting section including a signal input module and an electro-optical converter module, while the receiving section is a photoelectric Converter module and a signal receiving module contains. The signal input module provides for inputting digital electrical signals to the electro-optic transducer module while the electro-optic transducer module converts the digital electrical signals into light signals. The converted light signals are relayed to the photoelectric conversion module by means of the optical fiber cable, while the photoelectric conversion module converts the light signals into the digital electrical signals, the signal receiving module for receiving the digital signals converted by the photoelectric conversion module.

In 2 becomes a first single chip U1 used with the model drawing "Y51S019P" as a signal input module, wherein the first single chip U1 connected so that its pins 2 . 5 . 8th . 11 . 17 be grounded while his other pins 1 . 2 . 4 . 6 . 7 . 9 . 10 . 12 be electrically connected to the electro-optical converter module. In relation to 3 is preferably a VCSEL chip U2 used as the electro-optical transducer module, the VCSEL chip U2 connected so that its pins 27 . 28 . 30 . 31 . 33 . 34 . 36 and 37 each by means of a capacitor C1 . C2 . C3 . C4 . C5 . C6 . C7 . C8 with the pins 1 . 3 . 4 . 6 . 7 . 9 . 10 . 12 of the chip U1 get connected. The pins 8th . 19 are connected to the power supply module while the pins 1 . 20 . 26 . 29 . 32 . 35 be grounded, with the pins 24 . 25 each with a resistor R1 or. R2 be grounded. In one embodiment, the chip transmits U1 electrical digital signals via its pins 1 . 3 . 4 . 6 . 7 . 9 . 10 . 12 to the VCSEL chip U2 while the VCSEL chip U2 converts the electrical digital signals into light signals, which are then forwarded via the optical fiber cable to the photoelectric converter module. According to 4 For example, the photoelectric conversion module is preferably a PIN_PD driver chip U3 that is connected to his pins 3 . 24 be connected to the power module while its pins 8th . 10 be grounded, with its pins 21 . 22 each with a resistor R3 or. R4 grounded and his pins 9 . 10 . 12 . 13 . 15 . 16 . 18 . 19 be electrically connected to the signal receiving module. In relation to 5 is preferably a second single chip U4 used with the model drawing "Y51S019P" as a signal receiving module, where the pins 2 . 5 . 8th . 11 . 17 of the second single chip U4 be grounded while the pins 1 . 3 . 4 . 6 . 7 . 9 . 10 . 12 each with the pins 9 . 10 . 12 . 13 . 15 . 16 . 18 . 19 of the PIN_PD driver chip U3 connected to the PIN_PD driver chip U3 the converted digital electrical signals to the second single chip U4 can forward.

According to 3 is ever a connecting wire between the capacitors C1 . C2 . C3 . C4 . C5 . C6 . C7 . C8 and the first single chip U1 attached, wherein the individual connecting wires each have a resistor R12 . R11 . R10 . R9 . R8 . R7 . R6 . R5 be connected to the power supply module to provide a bias voltage and an impedance match for one between the first single chip U1 and the VCSEL chip U2 provide available signal transmission.

According to 4 is ever a connecting wire between the pins 9 . 10 . 12 . 13 . 15 . 16 . 18 . 19 of the PIN_PD chip U3 and the second single chip U4 attached, wherein the attached connecting wires in each case via an inductor FB1 . FB2 . FB3 . FB4 . FB5 . FB 6 . FB 7 . FB 8 be connected to the power supply module to a resonance frequency adjustment between the second single chip U4 and the PIN_PD driver chip U3 to realize.

In the embodiment, when the HDMI connection device according to the present invention connects a player to a screen, the HDMI connection device usually starts its work only after the receiving section has received a power signal from the transmission section.

In order to indicate a successful transmission of the current signal from the HDMI connecting device, the signal input module and the signal receiving module are electrically connected to each other in the embodiment as shown in FIG 1 is shown, wherein the signal input module is still connected in the order with a first control switch and a first LED module. Specifically, the pins are said 15 . 16 . 18 . 19 of the first single chip U1 each with the pins 15 . 16 . 18 . 19 of the second single chip U4 connected as it is in the 2 and the 5 connected, with the pins 15 . 16 of the first single chip U1 be connected to the first control switch. According to 6 becomes a chip U5 with the model name "1001" used as the first control switch, the chip U5 connected so that its pin 2 is grounded while its pin 5 connected to the power supply module. The pins 1 . 3 of the chip U5 Be there with the pins 16 . 15 of the chip U1 connected. The pin 6 is connected to the first LED module. The first LED module is a light emitting diode D1 whose anode has a resistor R13 with the pin 6 of the chip U5 is connected while the cathode is grounded. To detect a normal transmission of the current signal, the current signal is passed through the pin 18 of the chip U1 in the chip U4 entered. After the chip U4 has received the signal, a high level on the pin 19 to the chip U1 returned, with HDMI related information about the pins 15 . 16 to the chip U1 be returned. At the same time the signals on the pins 15 . 16 of the chip U4 in the chip U5 entered. After the chip U5 received the signal, he switches the LED D1 so that it lights up, which means a normal transmission of the current signal. In contrast, if the chip U4 the current signal is not received, no signal is sent to the chip U1 returned. This is how the LED lights up D1 not on, because no signal thereby the chip U4 triggers, which means that the transmission of the current signal does not occur.

After the successful transmission from the power signal is detected, it is further determined whether transmission of the digital signals between the transmission section and the reception section is normal. For this purpose, the signal receiving module is connected in the embodiment in the order with a second control switch and a second LED module, as shown in the 1 is shown. Concretely, the second control switch is a metal oxide semiconductor Q1 while the second LED module is a light emitting diode D2 is how it is in the 4 and the 7 is shown. The drain terminal of the metal oxide semiconductor Q1 is connected to the power supply module, while the source terminal of the metal oxide semiconductor Q1 about a resistance R14 with the anode of the LED D2 connected is. The cathode of the LED D2 is grounded while the gate terminal of the metal oxide semiconductor Q1 with the pin 23 of the PIN_PD chip U3 is connected. To determine whether the transmission of the digital electrical signals between the transmit section and the receive section is OK, the PIN_PD chip receives U3 the digital signals and makes on the basis of this a corresponding assessment. If all four channels of the PIN_PD chip U3 have received the digital signals, the four channels each send a signal through their pins to the metal oxide semiconductor to turn on the metal oxide semiconductor, so that the light emitting diode D2 lights up, which means a normal transmission of the digital signals between the transmitting section and receiving section. If at least one of the four channels receives no signal, then the PIN_PD chip is present U3 no signal that drives the metal oxide semiconductor so that the light emitting diode D2 does not light up, which means unsuccessful transmission of the electrical digital signals between the transmitting section and the receiving section.

How out 9 and 10 can be seen, is the fiber optic cable 31 the inventive HDMI connection device for the active optical fiber cable in the embodiment with a spiral-shaped elastic metal sleeve 33 envelops. In the spiral-shaped elastic metal sleeve 33 are also an electrical conductor 32 which interconnects the signal input module and the signal receiving module, and a filling material, which restricts a sliding movement of the optical fiber cable and the electrical conductor cable relative to the spiral-shaped elastic metal sleeve arranged. The outer circumference of the optical fiber cable and the electrical conductor cable is additionally a rubber sleeve 35 arranged surrounding the helical elastic metal sleeve, wherein the filling material 34 between the spiral elastic metal sleeve 33 and the rubber sleeve 34 is arranged and the relative sliding movement between the rubber sleeve 35 and the spiral metal sleeve 33 limited.

According to 11 let the positions of the rubber sleeve 35 and the spiral metal sleeve 33 exchange with each other, which can also fulfill the object of the present invention.

The filling material 34 is made of Kevlar fibers from DuPont, with the Kevlar fibers along a longitudinal direction of the spiral elastic metal sleeve 33 are arranged. Because the Kevlar fibers are a composite material having particular properties such as high tensile strength and lower density, the tensile strength of the electrical conductor cable becomes 32 and the fiber optic cable 31 increased so that the corresponding conductors are protected from tearing. The rubber sleeve 35 is made of TPU [thermoplastic polyurethane]. Because the TPU is one of the thermoplastic elastomers, it has a wide hardness range, high mechanical strength, excellent cold resistance, good machinability, oil resistance, water resistance, and mildew resistance. The spiral-shaped elastic metal sleeve 33 consists of a stainless steel reinforcement and serves, among other things, the fiber optic cable 31 and the electrical conductor cable 32 to protect from damage by tearing, scratching or pinching, which increases the reliability of the product.

The foregoing description illustrates the embodiments of the invention and is not intended to limit the claims. All equivalent changes and modifications that may be made by those skilled in the art in accordance with the description and drawings of the invention are within the scope of the present invention.

Claims (8)

An HDMI cable connecting device for an active optical fiber cable, comprising a transmitting section, a receiving section, a fiber optic cable and a power supply module, wherein the power supply module supplies power to the transmitting section and the receiving section, the transmitting section comprising a signal input module and an electro-optical converter module, while the receiving section is a photoelectric Transducer module and has a signal receiving module, and wherein the signal input module for inputting electrical digital signals in the electro-optical converter module, while the electro-optical converter module converts the digital electrical signals into light signals, and wherein the converted light signals are forwarded by means of the optical fiber cable to the photoelectric converter module, while the photoelectric Converter module converts the light signals into the digital electrical signals, wherein the signal receiving module ensures that through the photo electrical converter module to receive converted digital signals. HDMI connection device after Claim 1 , characterized in that the signal input module is a first single chip (U1) with the model designation "Y51S019P", wherein the electrooptical transducer module is a VCSEL driver chip (U2), and wherein the signal receiving module is is a second single chip (U4) with the model designation "Y51S019P", and wherein the photoelectric conversion module is PIN_PD driver chip (U3), and wherein the first single chip (U1), the VCSEL driver chip (U2), the PIN_PD Driver chip (U3) are electrically connected to each other, and wherein the second single chip (U4) is electrically connected to the PIN_PD driver chip (U3). HDMI connection device after Claim 2 , characterized in that between the first single chip (U1) and the VCSEL driver chip (U2), a bias and impedance matching module is connected. HDMI connection device after Claim 2 , characterized in that between the PIN_PD driver chip (U3) and the second single chip (U4), a resonant frequency adjustment module is connected. HDMI connection device after Claim 1 characterized in that the signal input module is electrically connected to the signal receiving module, the signal input module further comprising a first control switch and a first LED module, wherein the signal input module is configured to send a power signal to the signal receiving module, and wherein the signal receiving module is configured to send a high level signal to the signal input module after receiving the power signal and wherein the signal input module is configured such that upon receipt of the high level signal, a control signal may be sent to the first control switch, and wherein the first control switch is configured to control the control signal to control actuation of the first LED module to receive. HDMI connection device after Claim 1 characterized in that the signal receiving module is sequentially connected to a second control switch and a second LED light module, wherein the signal receiving module is configured to receive a digital electrical signal and then to send a control signal to the second control switch, and wherein the second control switch is configured so that the second LED light module is operated after the control signal has been received. HDMI connection device after Claim 1 characterized in that the optical fiber cable (31) is enveloped with a spiral elastic metal sleeve (33), further comprising an electrical conductor cable (32) connecting the signal input module and the signal receiving module and a filler material providing sliding movement of the optical fiber cable and the electrical conductor cable opposite to the spiral-shaped elastic metal sleeve prevents are arranged. HDMI connection device after Claim 7 characterized in that the filling material (34) is made of Kevlar fibers from DuPont, the Kevlar fibers being arranged along a longitudinal direction of the spiral elastic metal sleeve (33).

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