JPH03207146A - Data communication device - Google Patents

Abstract

PURPOSE:To enable a fast communication even if a distribution of data has a deviation by calculating the histogram of data to be sent and determining a transmission frequency to be assigned to the data according to the calculation result. CONSTITUTION:A CPU 14 calculates the histogram of the data (original data) sent from a host and the relation between the original data and transmission frequency is assigned according to the calculation result and then coded. The transmission frequency is assigned in decreasing transmission frequency order to the higher frequency of the original data so that even if the original data distribution has the deviation, the communication speed is not delayed so much. the assigned transmission frequency is coded and a frequency modulating circuit 18 modulates the code at the assigned transmission frequency to generate an MFM signal, which is sent. Consequently, even if the original data deviates, the fast communication can be made.

Description

Detailed Description of the Invention "Field of Industrial Application" The present invention is applied to a data communication device suitable for still image transmission Ml, etc., and is particularly applicable to speeding up communication when performing data communication using the MFM method. The aim is to ``Prior art'' In data communication devices such as still image transmission devices, MF
M (Multi Frequency Modulation)
There is a method that transmits data using a method.

In a data communication device using such an MFM modem (variable device), data to be transmitted and transmission frequency correspond to each other on a 1:1 basis for communication. In that case, for example, higher frequencies are assigned as the number of data values increases. Therefore, for example, data O has 100Hz, data 1
200Hz for data 2, 300H2 for data 2, 2100Hz for data 10, and so on. For example, now the data is 0. 10. 0.
When communicating data such as 10.0, 10, ..., 100Hz is used for one cycle, and 2100H2 is used for one cycle.
The data will be transmitted in the following manner.

On the receiving side, the transmitted data is demodulated by detecting these frequencies that are repeated at predetermined intervals.

``Problem to be solved by the invention'' If frequencies are allocated so that the transmission frequency increases as the size of the original data to be transmitted increases, the time required to transmit a certain amount of original data will be reduced. Since it is inversely proportional to the transmission frequency of the data, the total transmission time varies depending on the distribution of the original data.

As a result, if the distribution of original data is biased towards the lower frequencies used, the transmission speed of the original data will slow down and the transmission efficiency may drop significantly. Therefore, the present invention takes these points into consideration and proposes a data communication device that is capable of high-speed communication even if the data distribution is uneven when transmitting data using the MFM method. .

"Means for Solving the Problem" In order to solve the above-mentioned problem, the present invention provides means for calculating a histogram of data to be transmitted, and means for determining a transmission frequency to be assigned to the data based on the calculation result. It is characterized by having the following. "Operation" On the transmitting side, a histogram of the data (original data) sent from the host is calculated by the CPU 14, and the relationship between the original data and the transmission frequency is assigned based on the result and then encoded.

The relationship between transmission frequencies assigned to original data is such that even if the original data distribution is uneven, a higher transmission frequency is assigned to the frequency of the original data so that the communication speed does not slow down too much.

The assigned transmission frequency is coated, and the coat is modulated with the assigned transmission frequency in the frequency modulation circuit 18 to generate the M F M IN signal, which is then transmitted. At this time, demodulation data indicating the relationship with the transmission frequency assigned to the original data is also frequency modulated and then transmitted.

On the receiving side, this MFM signal is received and its transmission frequency is demodulated in the demodulation circuit 24. that time,
Demodulation data indicating the relationship between the original data and the transmission frequency is taken into the CPU 26, and the relationship between the original data and the transmission frequency is decoded. The MFM signal is decoded with reference to this demodulation data. Embodiment Next, a case in which an example of the data communication device according to the present invention is applied to the above-mentioned still image transmission device will be described in detail with reference to FIGS. 1 and 2.

FIG. 1 shows a transmitting device 10 of the still image transmitting device,
FIG. 2 shows a receiving device 20. As shown in FIG.

In the transmission station 10, still image data (original data) is supplied to the terminal 4 from the host side. This original data is temporarily stored in the transmission data buffer 12 with sufficient capacity.

When a predetermined number of original data is stored in the data buffer 12, the l block of original data is sent to the CPU 14 and a data histogram (
The frequency distribution of the original data) is calculated.

For example, image data has four gradations (0, 1, 2,
3), this four-level data (
(original data) is calculated. Therefore, for example, the gradation of image information with a total number of pixels of 100 to be transmitted is: Original data of floor Wl40...20% Original data of gradation 1...30%Original data of floor l12...-40% Original data of gradation 3...10%
When the distribution is as follows, the original data of gradation O... frequency 20 original data of gradation 1... frequency 301 original data of tone 2... original data of frequency 40 gradation 3... Frequency 1
0, and the magnitude of the frequency is arranged from the largest to the FI
Key 2-Rt Key 1-[l! The order is 10th floor rl43.

The CPU 14 determines the relationship between transmission frequencies to be assigned to the original data based on the histogram distribution so that the communication speed of the transmission block is minimized.

In this example, a higher transmission frequency is assigned in the order of the frequency of the original data. When the Imu1 information to be transmitted is expressed in 111th tone, the transmission frequency is
100Hz, 200Hz. 300Hz. Assuming that a frequency of 400 Hz is allocated, the relationship between the original data and the transmission frequency at this time is as follows.

Original data of Fil tone 2... Original data of 40 OHZ PI tone 1... Original data of 300 Hz level 1 lO... Original data of 200 Hz PI ill 3 - - - In the 100 Hz coating circuit 16, the original data calculated by the CPU 14 The original data is encoded based on the relationship between the histogram and the transmission frequency. In other words, in descending order of frequency, for example, "1 1", "1 0", "0 1", "
00" code will be applied. This uniquely defines the relationship between the code and the transmission frequency.

Note that when the original data is expressed in four gradations, there are 24 possible histogram intervals of the original data, so the encoding circuit 16 can be configured by, for example, a mapped ROM.

In this example, in addition to these, the coding circuit 16 outputs information indicating the relationship between the original data and the code, that is, whether the original data is assigned to the transmission frequency of the code (demodulation code F). It is designed so that

The code produced by the encoding circuit l6 is supplied to a modulation circuit 18, where the code is modulated by a predetermined transmission frequency.

In other words, for example, when the code "11" is manually generated, it becomes 4.
The transmission frequency of 00Hz is output for one period, and the code "]O
When J is operated manually, a transmission frequency of 300Hz is output for one period. The modulated data is transmitted to the other party using a transmission means (not shown).

Prior to these frequency modulations, the demodulation code described above is modulated at a specific frequency and transmitted together with the image data.

FIG. 2 shows an example of the receiving device 20. The received signal supplied to the terminal 22 is supplied to the demodulation circuit 24 to demodulate the received frequency, and the demodulated signal is sent to the CPU 26.
is supplied to Since the CPU 26 is prepared with the same memory map as the data of the encoding circuit 16, the CPU 2
The relationship between the transmission frequency and the code is decoded based on the demodulation code input to B, and the demodulated signal is further decoded by the decoding circuit 28 based on the decoded data to demodulate the original data.

This reconstructed original data obtained at terminal 30 is supplied to the host computer to reproduce the original image information.

If the most efficient transmission frequency correspondence is determined from the distribution of original data and communication is performed in this way, even if the distribution of original data is uneven, the data transmission speed will be slowed down. Never.

Next, a specific example will be shown.

Consider communicating image data under the following conditions. Number of pixels on one screen 64k = 65536 dots Number of gradations
4 (0. 1. 2. 3) Frequency used
100Hz. 200Hz300Hz. 4
0 0 H2 usage cycle One cycle per pixel If each gradation is uniformly distributed by 25%, the time required to transmit l screen is (0.25X) regardless of the correspondence between gradation and frequency. (1/100)+0.25X (1/
200)+[. 25X (+/300)+0.25X(
1/400))

Gradation 0:20%. Gradation rRl: 30%, Gradation 2: 4
0%. Gradation 3: 10% If frequencies are assigned in ascending order of data, the communication time is [11JO: 100Hz. Gradation 1: 2
00H2, NWA2: 3 0 0 Hz. floor l
! I3: Since it becomes 400Hz, < 0.20x (1/+00) + 0.30X (+/
200)+0.40x (+/300)+O. IOX
(1/400) > X 65536'; 333,
It will be 1 second. When a frequency is assigned to each data drop, the communication time is as follows: Gradation 0: 400 Hz. Floor Ill: 3
00HZ. Gradation 2: 200Hz. PJll3:
Since it is 100Hz, (0.10x (1/100) + 0.40X (1/
200)+0.30x (]/300)+0.20X(
1/400) } X65536 #294.9 seconds.

As shown in this invention, if higher frequencies are assigned in descending order of data based on the histogram distribution, gradation 0: 200Hz. PI! Ill: 300H
z. Rl 714 2: 400 Hz.
Floor rA3: 100Hz, {0.10x (1/100) + 0.20x (1/20
0)+0.30X (+/300)+0.40X(1/
400) ) X65536 ξ262, 1 second.

In this way, even if there is some bias in the distribution of data to be transmitted, the device according to the present invention provides faster communication than conventional devices.

"Effects of the Invention" As explained above, according to the configuration of the present invention, communication is performed by determining the most efficient transmission frequency correspondence from the distribution of original data. Even if the distribution of data is uneven, it will not slow down the data transmission speed.

Therefore, even if the original data is biased, high-speed communication is possible, which has the practical benefit of significantly improving data transmission efficiency.

[Brief explanation of drawings]

FIG. 1 is a system diagram showing an example of a transmitting device of the data communication apparatus according to the present invention, and FIG. 2 is a system diagram showing an example of the receiving device. 1 0 ● 1 2 ● 14.26 ・ 1 6 ・ 1 8 ● 2 0 ・ 2 4 ◆ 2 8 ● ・Transmitter ●Data buffer 7 ・CPU ・Coding circuit・Modulation circuit・Receiving device・Demodulation circuit・Decoding circuit

Claims (1)

[Claims] (1) A data communication device comprising means for calculating a histogram of data to be transmitted, and means for determining a transmission frequency to be assigned to the data based on the calculation result.