JP3436214B2 - Data detection method and electronic device using the same - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data detection system and electronic equipment using the same, and more particularly to data detected by comparing data sent from a transmitting side via a transmission line with a reference voltage on the receiving side. The present invention relates to a detection method and an electronic device using the detection method.

[0002]

2. Description of the Related Art FIG. 4 shows an example of a conventional data detection method for detecting data sent from a transmission side through a transmission line by comparing it with a reference voltage on the reception side. In this data detection method, only data is transmitted from the transmitting side, and a reference voltage of a constant voltage level is set on the receiving side in order to discriminate between “0” and “1” of the transmitted data, and the transmitted data is transmitted. If the voltage level is lower than the reference voltage, it is determined to be "0", and if it is equal to or higher than the reference voltage, it is determined to be "1". Figure 5
It is a figure which shows the signal waveform of each part of FIG.

Referring to FIGS. 4 and 5, when transmitting data as from the transmitting side, the driver 1 on the transmitting side
The output of 1 has a waveform such as. The data transmitted through the transmission line 12 has a blunt waveform due to the attenuation in the transmission line 12 as described above. This data is input to the receiver 14 as input data. The reference voltage 13 generated on the receiving side is a constant voltage, and the data is received by the receiver 1 as data.
4 is input. At this time, if the data reference voltage 13 is set to an intermediate level between "0" and "1" like data-1, even if the data of "1" is transmitted on the transmitting side, it does not exceed the reference voltage 13. On the receiving side, it is determined to be "0", and the received data becomes -1. Further, when the reference voltage 13 is set to a low level like data-2, even if "0" is transmitted on the transmitting side, it does not fall below the reference voltage 13 and is erroneously determined as "1". There is.

[0004]

Attenuation in the transmission line often occurs when the frequency of data transmission is high or when the transmission line length is long, but the frequency and the transmission line length as shown in FIG. 4 are fixed. Focusing on only one transmission circuit, the attenuation of the transmitted data waveform is
It is affected by the arrangement of 0's or "1's (continuity of" 0 "or" 1 "). For example, when the data waveform changes from" 0 "to" 1 "by 1 bit and in multiple bits. The potential on the receiving side is different even if the same "1" occurs when "1" continues, but in the above-described conventional data detection method, the reference voltage generated and referenced on the receiving side is Since the voltage is constant, there is a problem that accurate data detection cannot be performed on the receiving side.

It is an object of the present invention to solve the above problems and provide a data detection method capable of accurately detecting data on the receiving side and an electronic device using the same.

[0006]

[0007]

The first data detection scheme SUMMARY OF THE INVENTION The present invention transmits data to the receiver of the reception side through a transmission path from the transmitting-side driver, the voltage of the data input to the receiver This is a data detection method in which the receiving side determines "0" or "1" of the data by comparing with a reference voltage.
1 "is detected for each 1 bit, and the reference voltage is set for each 1 bit on the transmission side according to the continuity of the detected" 0 "," 1 ", and the reference voltage is synchronized with the data. Transmitting to the receiver via a transmission line, and comparing the data with the reference voltage in the receiver, thereby determining "0", "1" of the data for each bit on the receiving side. Is characterized by.

The second data detection method of the present invention detects "0" or "1" of the data inputted from the outside bit by bit and depending on the continuity of the detected "0" or "1". A reference voltage is set for each bit, and a control unit that outputs the reference voltage in synchronization with the data, and the data output from the control unit are input, and the receiver side receiver receives the data via the transmission path. A first driver transmitting to one input terminal and a reference voltage output from the control unit are input,
The second driver transmitting to the other input terminal of the receiver via the transmission line, the voltage of the data received from the first driver, and the reference voltage received from the second driver are compared, It is characterized by having a receiver for judging "0" and "1" of data.

According to a third data detection method of the present invention, a driver for transmitting data and a reference voltage, and data and a reference voltage from the driver via a transmission line are received and the respective voltages are compared. "0", "of the above data
In addition to having a plurality of circuits each of which is a receiver for determining 1 ", it detects the circuit of the output destination of the data input from the outside and also detects" 0 "or" 1 "of the input data bit by bit. And detected "0", "
A control unit that sets a reference voltage for each bit according to the continuity of 1 "and the attenuation characteristic of the output destination circuit, and outputs the reference voltage to the driver of the output destination circuit in synchronization with the data, It is characterized in that it is shared by a plurality of circuits.

A fourth data detection method of the present invention is the second or third data detection method of the present invention, in which data "0" or "1" is continuous as a result of the setting of the reference voltage in the control section. In this case, if the difference between the reference voltage of the current bit and the reference voltage of the previous bit is smaller than a predetermined threshold value, the reference voltage of the previous bit is set as the reference voltage of the current bit.

The electronic equipment of the present invention includes the first to fourth aspects of the present invention.
One of the above data detection methods is used.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention, in which data is input from the outside and the arrangement (continuity) of "0" and "1" of data is optimal at the receiving side. Control unit 1 that generates a voltage level (reference signal) that provides a different reference voltage and outputs the data and the reference signal in synchronization.
A driver 2 for transmitting the data and the reference signal output from the control unit 1, a transmission path 3 for transmitting the data and the reference signal transmitted from the driver 2, and a reference signal to which the data and the reference signal are input. And a receiver 4 that detects the data by comparing the voltage of 1 to the voltage of the data.

FIG. 2 is a diagram showing the signal waveform of each part of FIG. 1, and FIG. 3 is a diagram for explaining the reference voltage setting in the control part 1.

Next, the operation of the embodiment of the present invention will be described in detail with reference to FIGS.

First, the control unit 1 will be described. Generally, the attenuation in the transmission line is often generated when the frequency of the data transmission is high or the transmission line length is long. However, attention is paid to one transmission circuit whose frequency and transmission line length are fixed as shown in FIG. Then, the attenuation degree (attenuation characteristic) of the transmitted data waveform is influenced and changed by the arrangement of "0" or "1" (continuity of "0" or "1") in the data waveform. For example, when the data waveform changes from "0" to "1" by one bit and when "1" continues, even if the same "1", the potential on the receiving side is different. In order to change the reference voltage in accordance with the change in the attenuation of the data waveform, the control unit 1 determines the "0" and "1" of the input data from the arrangement (continuity) for each bit. An appropriate reference voltage is set and that voltage is output as a reference signal in synchronization with data.

Since the setting of the reference voltage is performed corresponding to the arrangement (continuity) of "0" and "1" of the data for each bit, the driver 2 of the target transmission circuit is set in advance.
From the test data to the receiver 4 via the transmission line 3 and observe the waveform of the attenuated data input to the receiver 4 to check each bit state (data "1" if continuous). When "0" continues, when data "1" to "0" is transmitted, when data "0" to "1" is transmitted, etc., the related voltage is set and stored in the control unit 1. I will leave it to you.

For example, the receiver 4 transmitted through the transmission line 3
Suppose that the input data to the input data has the waveform shown in FIG.
This waveform is a waveform when 6 bits of "1" and 6 bits of "0" are continuously transmitted as data. Voltage V
1 is the lowest potential of the transmission signal, and V5 is the highest potential of the transmission signal. V1 to V8 represent potentials of the transmission waveform, and VR1 to VR8 represent reference voltages. The time width of 1-bit data is 1 bit time.

When the data "1" is continuously transmitted from the potential V1, as shown in the waveform W1, V2 is obtained in 1 bit time,
It is assumed that V3 is reached in 2 bit time, V4 is reached in 3 bit time, and V5 is reached in 6 bit time.

When data "0" is continuously transmitted from the potential V5, as shown in the waveform W2, V6 is obtained in 1 bit time,
It is assumed that V7 is reached in 2 bit time, V8 is reached in 3 bit time, and V1 is reached in 6 bit time.

When transmitting 1 bit of "1" data,
In 1 bit time, the potential becomes V2. At this time, the potential of the reference signal is set to a value between V1 and V2, for example, an intermediate level between V1 and V2 [VR1 = (V2-V1) *, for example.
0.5 etc.]. The second bit data "1" is from V2 to V
3 and set VR2 to a value between V2 and V3, for example, an intermediate level between V2 and V3 [VR2 =
V2 + (V3-V2) * 0.5 etc.]. Similarly, VR3 is set from the data of the third bit. In the data from the 4th bit to the 6th bit, the amount of change in voltage is small, so V4 and V
A value between 5 and, for example, an intermediate level between V4 and V5 is VR4.

Similarly, the case of transmitting "0" data is set, and VR5, VR6, VR7 and VR8 are set.

In the case of changing from "0" to "1", the reaching potential V1 after 1 bit time, the reaching potential V2 after 2 bit time, the reaching potential V3 after 3 bit time,
Reaching potential V4 after 4 bit time, reaching potential V5 after 5 bit time, reference signals VR1 to VR4 for each bit time
And the reaching potential V6 after 1 bit time in the case of changing from "1" to "0", the reaching potential V after 2 bits time
7, reaching potential V8 after 3 bit time, reaching potential V1 after 4 bit time, reference signals VR5 to VR for each bit time
The voltage V1 is the lowest potential of the transmission signal, and the voltage V5 is the highest potential of the transmission signal. If the result of the calculation of the reference signal between V4 and V5 or between V8 and V1 shows that the amount of change in voltage is small, the threshold value is set in advance in the control unit in order to leave it at VR4 or VR8. If the change amount of the reference voltage does not exceed the threshold value, it is stored at the same value as the reference voltage of the previous bit.

Next, the operation of the control unit 1 when data to be transmitted to the control unit 1 is input will be described.

When the first 1 bit is "1" from the state of V1, the control unit 1 retrieves from the internal memory circuit and sets VR1 as the reference signal.

When the following bit is "0", the control unit 1 calculates that the reference signal is V2- (V5-VR5) because the reaching potential of the data of the previous bit is V2. .

When "1" is continuously input from V1 for 2 bits, the control unit 1 retrieves from the internal storage circuit and uses VR1 as the reference signal for the first bit and the reference signal for the second bit. VR2 is set respectively.

When 1 bit of "0" is input next to this state, the control unit 1 determines that the reference signal is V3- (V5- because the reaching potential of the data of the previous bit is V3.
Set as VR5).

When "0" is continuously input, the control unit 1 changes the reference signal to V3- (V5-V6)-(V6-
VR6) is set.

That is, in the reference signal, when the data "1" is continuous; when the potential data "0" which is higher than the reaching potential of the previous bit and lower than the reaching potential of the current bit (current bit) is continuous; When the potential data lower than the reaching potential of the bit and higher than the reaching potential of the current bit (current bit) is changed from "1" to "0": From the reaching potential of the previous bit- (V5-VR5) data "0" When changed to "1": Set as the reaching potential of the previous bit + (VR1-V1).

As described above, the control unit 1 performs the operation of determining the potential of the reference signal based on the continuity of "0" and "1" of the data to be transmitted.

Next, the overall operation of the data detection method shown in FIG. 1 will be described in detail with reference to FIGS.

First, data to be transmitted is externally input to the control unit 1. This input data is the data of the waveform shown in FIG.

The control unit 1 controls the input data to be "0".
1-bit sequence (continuity) of "1" and "1" is detected, and from the detected 1-bit sequence of "0" and "1", an appropriate reference voltage stored in the internal storage circuit is set to 1 bit. It is determined for each and the voltage is output as a reference signal in synchronization with data.

The data and the reference signal output from the control unit 1 are output to the transmission line 3 by the driver 2. At this time, the waveform of the data output from the driver 2 is the waveform shown in FIG. 2, and the waveform of the reference signal is like the waveform.

The data and the reference signal transmitted through the transmission line 3 are received by the receiver 4, but the waveform is blunted due to the attenuation in the transmission line 3, and the data input to the receiver 4 has the waveform shown in FIG. , The reference signal looks like a waveform.

Thereafter, the receiver 4 compares the voltage values of the data and the reference signal bit by bit. If the data is a voltage equal to or higher than the reference signal, the data is judged to be "1" and the data is less than the reference signal. If it is voltage, data is "0"
To judge. Then, the receiver 4 outputs the determination result as data. The output waveform of the receiver 4 is shown in FIG.
The waveform shown in (1) is obtained, and the same data as the waveform of the transmission data can be obtained at the receiving side, and the data transmission can be normally performed.

In the above-described embodiment, the transmission circuit is described as one circuit, but it is obvious that the present invention can be applied to a plurality of transmission circuits.
In this case, the control unit may be provided in a one-to-one correspondence with each transmission circuit, or may be provided in common with a plurality of transmission circuits. When one control unit is commonly provided for a plurality of transmission circuits, the control unit stores associated voltages such as V1 to V8 and VR1 to VR8 corresponding to the attenuation characteristics of each transmission circuit for each transmission circuit. Every other, identify which transmission circuit to output when there is data input to the control unit from the outside, and then set the reference voltage using the related voltage of the corresponding transmission circuit stored inside, The data may be output to the driver of the corresponding transmission circuit together with the synchronized data.

[0039]

According to the present invention, the potential of the reference signal is set on the transmission side according to the arrangement of "0" or "1" (continuity of "0" or "1") of the data waveform to be transmitted. , The set reference signal is transmitted from the transmitting side in synchronization with the data, and the receiving side compares the electric potential of the received reference signal with the electric potential of the data.
The effect of being able to perform accurate data detection on the receiving side is obtained without being affected by the attenuation due to the continuity of 1 ″.

Further, since the reference voltage for discriminating between "0" and "1" of the data is transmitted from the transmitting side, the influence of noise on the transmission line or the like is received by the reference signal as well as the data. It also has the effect of increasing the noise margin of data transmission.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of the present invention.

FIG. 2 is a diagram showing a signal waveform of each part of FIG.

FIG. 3 is a diagram for explaining reference voltage setting in the control unit 1.

FIG. 4 is a block diagram showing a configuration of a conventional technique.

5 is a diagram showing a signal waveform of each part of FIG.

[Explanation of symbols]

1 control unit 2 drivers 3 transmission lines 4 receiver

Front page continuation (58) Fields surveyed (Int.Cl. ⁷ , DB name) H04L 25/03 H04L 25/02 H03K 5/08

Claims (5)

(57) [Claims] 1. By transmitting data from a driver on the transmitting side to a receiver on the receiving side via a transmission line and comparing the voltage of the data input to the receiver with a reference voltage,
This is a data detection method in which "0" or "1" of the data is judged on the receiving side, and "0" or "1" of the data to be transmitted is detected bit by bit and detected "0" or "1". The reference voltage is set for each bit on the transmission side according to the continuity of ", and the reference voltage is transmitted to the receiver via the transmission line in synchronization with the data, and the receiver and the data are transmitted. By comparing the voltage with the reference voltage,
A data detection method characterized in that the receiving side determines 0 "or" 1 "bit by bit. 2. "0" or "1" of data input from the outside is detected bit by bit and detected "0", "
A reference voltage is set for each bit in accordance with the continuity of 1 ", and a control unit that outputs the reference voltage in synchronization with the data, and the data output from the control unit is input, and the transmission line is connected. A first driver for transmitting to one input terminal of the receiver on the receiving side via the second driver for transmitting the reference voltage output from the control unit to the other input terminal of the receiver via the transmission path;
And a receiver that compares the voltage of the data received from the first driver with the reference voltage received from the second driver to determine "0" or "1" of the data. Data detection method characterized by. 3. A driver that transmits data and a reference voltage, and receives data and a reference voltage from the driver via a transmission line, and compares the respective voltages to obtain "0", "of the data. It has a plurality of circuits consisting of a receiver that judges 1 ", detects the circuit of the output destination of the data input from the outside, and detects" 0 "or" 1 "of the input data bit by bit. Then, a reference voltage is set for each bit in accordance with the detected continuity of "0" and "1" and the attenuation characteristic of the output destination circuit, and the reference voltage of the output destination circuit is synchronized with the data. A data detection method characterized in that a control unit for outputting to a driver is shared by the plurality of circuits. 4. When the data "0" or "1" continues as a result of the setting of the reference voltage in the control unit, the difference between the reference voltage of the current bit and the reference voltage of the previous bit is a predetermined threshold. less than the value, the claim 2 or 3 data detection method, wherein the setting the reference voltage before the bit as the reference voltage of the current bit. 5. An electronic device characterized by using the data detection method of any one of claims 1-4.