KR20190083159A - Apparatus for evaluating performance of optical displayport cable - Google Patents

Abstract

Disclosed is an apparatus for evaluating performance of an optical display port cable. The apparatus comprises: a transmission side test board having a display port connector connected to a transmission end, and transmitting a test pulse to the transmission end through the display port connector; and a reception side test board having a connector connected to an external measurement device evaluating performance of the display port connector connected to a reception end and the optical display port cable, and transmitting an optical signal corresponding to the test pulse received through the reception end and the transmission end to the external measurement device through the display port connector.

Description

TECHNICAL FIELD [0001] The present invention relates to a performance evaluation apparatus for an optical display port cable,

The present invention relates to a display port cable, and more particularly, to a performance evaluation of an optical display port cable.

The display port cable is a cable connected between the source device and the sink device. It consists of four data lane channels, one AUX channel, and one HPD (Hot Plug Detect) channel. .

Of these display port cables, the DisplayPort cable is a fiber-optic data lane channel for high-quality, large-capacity data transmission, and is implemented using a 4-channel optical module.

On the other hand, the easiest way to evaluate the operation of the display port cable is to connect the manufactured display port cable to the source device and the sink device, and then check whether the video output is performed to determine whether the cable is operated or not. However, this method can only determine whether the cable is in operation or not, and can not know which part is the problem when the image is not outputted.

Accordingly, an object of the present invention is to provide a method and an apparatus for evaluating performance of a display port optical cable, which can easily evaluate the operation of a display port cable by evaluating characteristics of a data lane channel, an AUX channel and an HPD channel of a display port cable I have to.

According to an aspect of the present invention, there is provided an apparatus for evaluating the performance of an optical display port cable, the apparatus including: an optical display including a transmitting end connected to a source device, a receiving end connected to a sink device, and an optical cable connecting the transmitting end and the receiving end; A test apparatus for a port cable, comprising: a test terminal board having a display port connector connected to the transmitting terminal and transmitting a test pulse to the transmitting terminal through the display port connector; and a display port connector connected to the receiving terminal; And a connector connected to an external measuring device for evaluating the performance of the optical display port cable, wherein an optical signal corresponding to the test pulse received through the transmitting terminal and the receiving terminal through the display port connector is transmitted through the connector And a reception side test board for transmitting the group outside the instrument.

According to the present invention, performance can be tested without image transmission without connecting the display port cable to the display port of the PC and the monitor, in order to determine good and defective display port cables.

Further, by testing each of the main link (data lane), the AUX channel, and the HPD channel, the abnormal part can be determined in detail.

In addition, since the transmitter and receiver are separated and tested, the display port cable can be easily identified and the cost can be reduced by replacing only the defective portion.

1 is a configuration diagram of an optical display port according to an embodiment of the present invention.
2 is a detailed configuration diagram of the DP cable shown in Fig.
FIG. 3 is a diagram illustrating the configurations necessary for evaluating the performance of the transmitter shown in FIG. 2. Referring to FIG.
FIG. 4 is a diagram illustrating the configurations necessary for evaluating the performance of the receiver shown in FIG. 2. Referring to FIG.
5 is a flowchart illustrating a method of evaluating performance of an optical display port cable according to an embodiment of the present invention.

Best Mode for Carrying Out the Invention Various embodiments of the present invention will be described below with reference to the accompanying drawings. The various embodiments of the present invention are capable of various changes and may have various embodiments, and specific embodiments are illustrated in the drawings and the detailed description is described with reference to the drawings. It should be understood, however, that it is not intended to limit the various embodiments of the invention to the specific embodiments, but includes all changes and / or equivalents and alternatives falling within the spirit and scope of the various embodiments of the invention. In connection with the description of the drawings, like reference numerals have been used for like elements.

1 is a configuration diagram of an optical display port according to an embodiment of the present invention.

1, an optical display port (DP) 100 according to an embodiment of the present invention includes a source device 110 for transmitting multimedia, a sink device 120 for receiving an image, And a DP cable 130 for optically connecting the DP cables 130 and 130. For example, the display port cable 130 can be implemented as an optical fiber so as to transmit a large-capacity high-quality image even at long distances of 100 m or more.

The DP cable 130 may include a main link 131, an AUX channel 133 and a hot plug detect (HPD) signal line 135.

The main link 131 can be implemented as an optical fiber for transmitting a multimedia stream such as uncompressed video and audio as a single direction, a channel having a high bandwidth and a low call time, and transmitting a large-capacity high-quality image even at long distances . The main link 131 may be a dual-terminal differential pair of AC connections called " LANE ". Due to this AC coupling, the transmitter 112 of the source device 110 and the receiver 122 of the sink device 120 have different common mode voltages.

The AUX channel 133 is used for link management and device control, and can be configured as a half duplex bidirectional channel.

The HPD signal line 135 may comprise a channel that acts as a blocking request by the sink device 120.

2 is a detailed configuration diagram of the DP cable shown in Fig.

2, the DP cable 130 may be configured to include a transmitting end 130A, a receiving end 130B, and a connecting part 130C 131, 133, 135 connecting the transmitting end 130A and the receiving end 130B. have.

Transmitter (130A)

The transmitting terminal 130A is connected to the source device (110 of FIG. 1) and includes a transmitting side connector 130A-1, a transmitting side controller 130A-2, a converter 130A-3, The first side port 130A-4, the transmitting side substrate 130A-5, the optical subassembly (OSA) 130A-6, the transmitting side amplifier 130A-7 and the transmitting side second port 130A- .

The transmission side DP connector 130A-1 is electrically and physically connected to the transmitter (112, Tx in Fig. 1) of the source device (110 in Fig. 1) , And the source device 110 and the transmitting terminal 130A are communicably connected.

The transmitting-side controller 130A-2 controls the overall operation of the internal configurations 130A-1, 130A-3, ..., 130A-8 of the transmitting terminal 130A. For example, Controller Unit (MCU).

The transmitting-side converter 130A-3 converts the first signal input from the controller 130A-2 into a second signal and outputs the second signal inputted from the transmitting-side first port 130A-4 to the 1 signal and outputs it to the controller 130A-2. For convenience of explanation, the first signal is referred to as a UART signal and the second signal is described as a USB signal, but the present invention is not limited thereto. Thus, the converter 130A-3 according to the present embodiment may be, for example, a UART to USB converter or a USB to UART converter.

* UART (Universal Asynchronous Receiver / Transmitter), USB (Universal Serial Bus)

The transmitting-side first port 130A-4 transmits the USB signal input from the transmitting-side converter 130A-3 to the external device, and conversely transmits the USB signal inputted from the external device (not shown) through the USB cable To the converter 130A-3, and may be, for example, a USB mini (MiNi) port.

The connection substrate 130A-5 is connected to the transmission-side DP connector 130A-1. For example, the connection between the transmission-side substrate 130A-5 and the transmission-side DP connector 130A- LANE 0 to 3). The transmitting-side substrate 130A-5 may be a flexible PCB.

(VCSEL) 136A-6A that supports four channels on the transmission-side substrate 130A-5 to support the lanes (LANE 0 to 3) A VCSEL driver controller (VDC) 130A-5A is mounted.

Also, the transmission-side substrate 130A-5 may be connected to the controller 130A-2 by the I2C method.

The transmitting optical subassembly 130A-6 is configured to include a submount and a four-channel VCSEL 136A-6A mounted on the submount.

The transmission-side amplifier 130A-7 is connected to the transmission-side DP connector 130A-1 by the I2C method to amplify the AUX channel signal input from the transmission-side DP connector 130A-1.

The second port 130A-8 on the transmitting side receives the AUX channel signal amplified from the transmitting amplifier 130A-7 and the HPD channel signal from the receiving terminal 130B. For example, a USB micro- Port.

Receiver (130B)

The receiving end 130B is connected to the receiver (122, Rx in FIG. 1) of the sink device 120 (FIG. 1) and includes a receiving side DP connector 130B-1, a receiving side controller 130B- An optical subassembly (OSA) 130B-6, a receiver-side amplifier 130B-7, a receiver-side first port 130B- And a receiving-side second port 130B-8.

The receiving-side DP connector 130B-1 is electrically and physically connected to the receiver (122, Rx in FIG. 1) of the sink device (120 in FIG. 1) , And the sink device 120 and the receiving end 130B are communicably connected.

The receiving-side controller 130B-2 controls the overall operation of the internal configurations 130B-1, 130B-3, ..., 130B-8 of the receiving end 130B. For example, Controller Unit (MCU).

The receiving-side converter 130B-3 converts the UART signal input from the receiving-side controller 130B-2 into a USB signal and outputs the converted USB signal to the UART signal 130B- To the controller 130A-2, and may be, for example, a UART to USB converter or a USB to UART converter.

The receiving-side first port 130B-4 transmits the USB signal input from the receiving-side converter 130A-3 to the external device and conversely transmits the USB signal inputted from the external device via the USB cable to the receiving-side converter 130B -3), and may be, for example, a USB mini (MiNi) port.

The receiving board 130B-5 is a board connected to the receiving DP connector 130B-1 and may be a flexible PCB. The receiving board 130B-5 and the receiving DP connector 130B- 1) can be configured to support 4 lanes (LANE 0 ~ 3).

On the reception side substrate 130B-5, an IC chip 130B (130B-1) for processing the photocurrent detected by the photodetector (PD, 130B-6B) supporting four channels to support four lanes -5B are mounted. The IC chips 130B-5B include, for example, a transimpedance amplifier (TIA) that amplifies a weak optical current to a voltage signal and a limiting amplifier , LA).

The reception side controller 130B-5 and the reception side controller 130B-2 can be connected to communicate by the I2C communication method. Accordingly, the operation of the IC chip 130B- 2). ≪ / RTI >

The receiving side optical subassembly 130B-6 may be mounted with a submount and a photodetector PD (130-6B) supporting four channels mounted on the submount.

The receiving-side amplifier 130B-7 is connected to the transmitting-side DP connector 130A-1 by the I2C method to amplify the AUX channel signal input from the transmitting-side DP connector 130A-1 to support long- .

The receiving-side second port 130B-8 receives the AUX channel signal amplified by the transmitting-side amplifier 130A-7 and the HPD signal from the receiving-side DP connector 130B-1. For example, It may be a USB micro port.

The connection portions 130C (131, 133, 135)

The connection unit connects the transmitting end 130A and the receiving end 130B and includes a main link 131, an AUX channel 133, and an HPD channel 135. [

The main link 131 is implemented as a cable for communication connection between the transmission side optical subassembly 130A-6 and the reception side optical subassembly 130B-6, and is implemented as an optical fiber so as to transmit a high- Optical cable.

The AUX channel 133 and the HPD channel 135 may be implemented as wires connecting the transmitting second port 130A-8 and the receiving second port 130B-8.

As described above, the transmitting end 130A and the receiving end 130B are connected to the optical cable and the electric wire, and can communicate using various communication methods, and the communication method can be, for example, an I2C communication method.

As described above, the DP cable 130 includes optical elements such as amplifiers 130A-7, VCSEL 136A-6A, VDC 130A-5, photodetectors 130B-6B, IC chips 130B-5B, An optical property evaluation for determining whether the optical element and the integrated circuit chip pass or fail and the determination of whether or not the DP cable 130 is operating after the DP cable 130 is manufactured, A characteristic evaluation is required.

To this end, an apparatus for evaluating the performance of the DP cable of the present invention is shown in Figs.

Figure 3 shows the necessary arrangements for evaluating the performance of the transmitting terminal 130A in a DP cable according to an embodiment of the present invention,

3, the apparatus 140 for evaluating the performance of the transmitting terminal 130A in the DP cable 130 includes a power supply 141, a pulse generator 143, a transmitting test board 145, Analyzer < / RTI >

The power supply unit 141 is configured to supply power to the transmission terminal 130A in order to test the operation of the DP cable 130 with respect to the transmission terminal 130A. More specifically, the transmission side first port 130A-4 2) in the transmitting terminal 130A via the USB mini (MiNi) port, and the transmitting-side controller 130A-2 supplies power to the transmitting-side controller 130A- And starts operation.

The pulse generator 143 generates a test pulse corresponding to the transmission rate of the transmitting terminal 130A on the transmitting test board 145. [

The transmitting side test board 145 transmits the test pulse generated by the pulse generator 143 to the transmitting terminal 130A. Specifically, the transmitting side test board 145 includes a connector 145-1, a DP connector 145-3, And a port 145-5.

The connector 145-1 is electrically and physically connected to the pulse generator 143 to receive the test pulse. The connector 145-1 is electrically connected to the DP connector 145-3 through the patterned circuit wiring on the transmitting test board 145. [ This connector 145-1 includes a plurality of differential pair terminals 145-1A and is configured to include four differential pair terminals 145-1A to support four lanes LANE 0 to 3 . The connector 145-1 may be, for example, a SubMiniature version A (SMA) connector or a K-connector.

The DP connector 145-3 is electrically and physically connected to the transmitting-side DP connector 130A-1 in the transmitting terminal 130A and transmits the test pulse received from the connector 145-1 to the transmitting terminal 130A- .

The port 145-5 is connected to an external device that generates the test AUX channel signal to test the AUX channel and is connected to the DP connector 145-3 through the electric wiring on the transmitting test board 145 . Accordingly, the port 145-5 serves to transmit the test AUX channel signal to the transmitting terminal 130A through the DP connector 145-3. The port 145-5 also receives a test HPD channel signal from the transmitting terminal 130A via the DP connector 145-3 via another electrical wiring on the transmitting test board 145 to test the HPD channel And receiving it. This port 145-5 is the same type of port as the transmitting second port 130A-8 in the transmitting terminal 130A, and may be, for example, a USB micro port.

The signal waveform analyzer 147 is connected to the transmitting optical subassembly 130A-6 in the transmitting terminal 130A to analyze the waveform of the optical signal corresponding to the test pulse transmitted from the transmitting test board 145, And outputs an eye diagram as a result of the analysis.

The tester checks the eye diagram to determine whether or not the main link 131 is operating in the transmitting end 130A as well as both sides of the configurations 130A-5 and 130A-6 associated with the main link 131 Can be determined or predicted. The signal waveform analyzer 147 may be, for example, an oscilloscope.

FIG. 4 shows the configurations necessary to evaluate the performance of the receiving end 130B in the DP cable according to an embodiment of the present invention.

4, an apparatus 150 for evaluating the performance of the receiving end 130B in the DP cable 130 includes a receiving test board 151 and an error detector 153, and further includes a power supply unit And may further include a signal waveform analyzer. As the power supply unit and the signal waveform analyzer, the power supply unit 141 and the signal waveform analyzer 147 used for evaluating the performance of the transmitting terminal 130A can be used as they are.

The receiving side test board 151 includes a DP connector 151-1, a connector 151-3 and a port 151-5.

The DP connector 151-1 is electrically and physically connected to the receiving-side DP connector 130B-1 of the receiving end 130B. Therefore, the DP connector 151-1 receives the optical signal corresponding to the test pulse and the test AUX channel signal.

The connector 151-3 is electrically connected to the DP connector 151-1 via the patterned wiring on the receiving test board 151 to receive the optical signal. The connector 151-3 includes a plurality of differential pair terminals in the same manner as the connector 145-1 provided in the transmitting test board 145-1 and is provided with a plurality of differential pairs to support four lanes LANE 0 to LANE 3 , And four differential pair terminals.

The connector 151-3 is electrically and physically coupled to the signal waveform analyzer 147 and transmits the optical signal to the signal waveform analyzer 147. [ At this time, the optical signal is transmitted to the signal waveform analyzer 147 through some differential pair terminals among a plurality of differential pair terminals. The signal waveform analyzer 147 analyzes the waveform of the optical signal and outputs an eye diagram as a result of the analysis. The tester checks the eye diagram to determine the correctness of the parts associated with the main link within the receiving end 130B.

The connector 151-3 is electrically and physically coupled to the error detector 153 and transmits the optical signal to the error detector 153. [ At this time, the optical signal inverted through the remaining differential pair terminals among the plurality of differential pair terminals is transmitted to the error detector 153. The error detector 153 analyzes the inverted optical signal and measures the error bit rate to determine the amount of components associated with the main link 131 within the receiving end 130B.

The port 151-5 is connected to the patterned wiring 151B on the receiving test board 151 to test the performance of the components (e.g., amplifier 130B-7) associated with the AUX channel within the receiving end 130B. To the DP connector 151-1. Therefore, the port 151-5 can receive the test AUX channel signal from the DP connector 151-1.

The port 151-5 also receives the test HPD channel signal from the outside and sends it to the transmitting test board 145 via the DP connector 151-1 to determine the parts of the parts associated with the HPD channel Lt; / RTI > Upon receipt of the test HPD channel signal on the transmitting side test board 145, a measuring instrument such as an oscilloscope is connected to the port 145-5 of the transmitting side test board 145 to measure the voltage level (High / Low ) To determine whether the HPD channel is positive or negative.

This port 151-5 is the same type of port as the receiving second port 130B-8 in the receiving end 130B, and may be, for example, a USB micro port.

5 is a flowchart illustrating a method of evaluating performance of an optical display port cable according to an embodiment of the present invention.

Referring to FIG. 5, first, in step S511, a test for an HPD channel is performed. In order to perform a test on the HPD channel, a test HPD channel signal is applied to the port 151-5 of the receiving test board 151 and the port 151-5 of the receiving test board 145 is measured using a measuring instrument such as an oscilloscope (USB micro port) to determine the connection between the transmitting end 130A and the receiving end 130B and the connection to the HPD channel. For example, when a high level voltage is measured at the port 145-5 of the transmitting test board 145, the HPD channel is determined to be normal, and when the voltage of the low level is measured , It is judged to be defective.

If it is determined in step S513 that the HPD channel is defective, the test HPD channel signal is again applied to the port 151-5 of the receiving test board 151 and the port of the transmitting test board 145 And then the voltage level of the signal 145-5 is measured again. If the HPD channel is determined to be defective continuously for a plurality of times, the patterned wiring on the transmitting side board 145 of the transmitting terminal 130A, the parts mounted around the wiring, and other parts related to the HPD channel are changed, Repeat the test for the channel. The receiver 130B repeatedly tests the HPD channel while replacing the parts in the same manner.

Then, if the HPD channel is determined to be normal in step S513, a test is performed on the AUX channel in step S515. The test AUX channel signal is applied to the port 145-5 of the transmitting side test board 145 and the port 151 of the receiving side test board 151 is selected according to the I2C communication method in order to perform the test for the AUX channel -5), the test for the AUX channel is judged to be normal when reception of the same signal as the test AUX channel signal is confirmed.

Subsequently, in step S517, if the test for the AUX channel is determined to be abnormal, the patterned wiring on the transmitting side board 145 of the transmitting terminal 130A, the components mounted around the wiring, for example, the transmitting side amplifier 130A- 7) and so on, and other parts associated with the AUX channel. At the receiving end 130B, the test for the AUX channel is repeated while the parts are changed in the same manner.

Then, if it is determined in step S517 that the AUX channel is normal, a performance test of the transmitting terminal 130A with respect to the main link 131 is performed in step S519. A test pulse is applied to the DP connector 145-1 of the transmission test board 145 and the test pulse is applied to the transmission side optical subassembly in the transmission stage 130A in order to perform the transmission stage 130A test on the main link 131. [ The eye diagram of the optical signal corresponding to the test pulse is confirmed by using the signal waveform analyzer 147 connected to the test signal generator 130A-6.

Then, in step S521, if an abnormal determination of the eye diagram is confirmed several times, the related parts in the transmitting terminal 130A (the patterned wirings on the transmitting substrate 130A-5 associated with the data lane, VDC, VCSEL, etc.), or repeat the confirmation of eye diagrams one by one.

If the normal determination of the eye diagram is confirmed in step S521, a performance test of the receiving end 130B with respect to the main link 131 is performed in step S523. In step S525, the signal waveform analyzer 147 connected to the DP connector 151-3 of the receiving test board 151 is used to perform the performance test of the receiving end 130B, The eye diagram of the signal is checked, and the explanation is similar to the process of confirming the eye diagram performed in the transmitter test. That is, the related parts in the receiving end 130A (the wirings patterned on the receiving side substrate 130A-5 associated with the data lane, PD, IC chip, TIA, LA, Diagram again.

If a normal eye diagram is confirmed, in step S527, an error detector 153 connected to the DP connector 151-3 of the receiving test board 151 is used to check the data transmission rate. That is, when the error bit rate detected by the error detector 153 exceeds the threshold value, the data rate is determined to be abnormal, and the related parts (PD, TIA, LA or the like) is checked or changed one by one, and the data transmission rate is checked again. When the data transmission rate is all determined to be normal, a series of processes for evaluating the performance of the optical display port cable are terminated.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood that various modifications and applications not illustrated in the drawings are possible. For example, each component specifically shown in the embodiments of the present invention can be modified and implemented. It is to be understood that all changes and modifications that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims (1)

A transmitting end connected to the source device, a receiving end connected to the sink device, and an optical cable connecting the transmitting end and the receiving end,
A transmitting test board having a display port connector connected to the transmitting terminal and transmitting a test pulse to the transmitting terminal through the display port connector; And
A display port connector connected to the receiving end and a connector connected to an external measuring device for evaluating the performance of the optical display port cable, wherein the test pulse received through the display port connector, And a receiving side test board for transmitting a corresponding optical signal to the external measuring instrument via the connector.

Images