JPH02140816A - Unbalance/balance converter for scsi - Google Patents

Abstract

PURPOSE:To mutually connect SCSI devices different in types by arranging two converters between an unbalanced type SCSI device and a balance type SCSI device and using them by means of switching. CONSTITUTION:An unbalance/balance converter for SCSI (Small Computer System Interface) 300 is connected in parallel between the device 100 provided with unbalanced type SCSI and the device 200 provided with balanced type SCSI. When the first converter 10 is in an operation state by a switching means 30, a pair of signal data outputted from the balanced type device 200 are converted into single signal data by the converter 10 and are given to the unbalanced type device 100. When the second converter 20 is in the operation state, single signal data outputted from the unbalanced type device 100 is converted into a pair of signal data by the converter 20 and they are given to the balanced type device 200. Thus, the SCSI devices different in the types can mutually be connected.

Description

Detailed Description of the Invention [Field of Industrial Application] The present invention relates to an unbalanced/balanced converter for SCSI I, particularly a device equipped with an unbalanced SCSI and a device equipped with a balanced SC8. The present invention relates to a converter for connecting between devices to transfer data between devices.

[Conventional technology]

With the spread of computer-related devices, various interfaces for interconnecting these devices have been developed. Among such interfaces, SCSI for small computer systems
(Small CoButer SystemInte
rface) is beginning to become popular. Generally, a host computer as an initiator issues instructions to a disk device or printer device as a target.
A host computer and a disk device or a printer device are connected via a SCSI bus to transfer data. Currently, there are two types of 5C3I signaling systems:

(1) Unbalanced type (Slngle 1Ended) 1
Only one signal line is used for each signal. With open collector output, "L" level becomes "true" logic.

(2) Balanced type (Dlfrerentral) Two signal lines, a child signal line and a single signal line, are used for one signal. The logic becomes "true" when the level of the child signal becomes higher than the level of one signal. Two signal lines are required, but it is more resistant to noise.

[Problem to be solved by the invention]

As mentioned above, there are two types of SCSI signaling systems: unbalanced type and balanced type, but conventionally it has not been possible to connect devices of these different types using a common SCSI bus. Therefore, even if there are two devices equipped with SCSI, a problem has arisen in that they cannot be connected to each other if their signal systems are different.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide an unbalanced/balanced converter for SCSI that can interconnect different types of SCSI devices.

[Means to solve the problem]

The present invention provides a converter for connecting between a device equipped with an unbalanced SCSI and a device equipped with a balanced SCSI to perform data transfer between the devices. A first converter having two input terminals, an input terminal and a negative input terminal, and an output terminal that outputs a signal based on a difference between signals applied to both input terminals,
Connect the two input terminals to a pair of balanced SCSI input/output terminals in a device equipped with a balanced SCSI, and connect the output terminals to an unbalanced 5C8I input/output terminal in a device equipped with an unbalanced SCSI. It has an input terminal and two output terminals, a positive output terminal and a negative output terminal, and outputs two signals with a difference determined based on the signal input from the input terminal to both output terminals. Prepare a second converter with the function of I to unbalanced SCSI In the case of transfer, switching means is further provided which has the function of placing the second converter in the operating state and placing the first converter in the high impedance state.

[For production]

When the first converter is in operation, a pair of signal data output from a balanced SCSI having two input/output terminals is converted into a single signal data by the first converter, and It is applied to an unbalanced SCSI I having an output terminal. When the second converter is in operation,
A single signal data outputted from an unbalanced SCSI having a single input/output terminal is converted into a pair of signal data by a second converter, and provided to a balanced SCSI having a pair of input/output terminals. Bidirectional data transfer is thus possible, and when one converter is in operation, the other converter is in a high impedance state, so that the signal is not disrupted.

〔Example〕

The present invention will be described below based on illustrated embodiments. 1st
The figure is a block diagram showing the basic configuration of the unbalanced/balanced converter for SC9I according to the present invention connected between two devices. Here, a device 10 equipped with an unbalanced SCSI
An unbalanced/balanced converter 300 for 5C8I according to the present invention is connected between 0 and the device 200 equipped with a balanced SCSI.

This converter 300 includes a first converter 10, a second converter 20, and a switching means 30. The first converter 10 has a positive input terminal 11 and a negative input terminal 1
2, and an output terminal 13 that outputs a signal based on the difference between the signals applied to both input terminals. The two input terminals 11 and 12 are each connected to a pair of balanced 5C3I input/output terminals 201 and 202 in the device 200 equipped with a balanced SCSI, and the output terminal 13 is equipped with an unbalanced SCSI. It is connected to an unbalanced SCSI input/output terminal 101 in the device 100. On the other hand, the second converter 20 has an input terminal 21 and two output terminals, a positive output terminal 22 and a negative output terminal 23. Two signals having a difference determined based on the signals input from the input terminals are output to both output terminals 22 and 23. The two output terminals 22 and 23 are connected to two balanced 5C8I input/output terminals 202 and 201, respectively, and the input terminal 21 is connected to the unbalanced SCSI input/output terminal 101. Furthermore, when data is transferred from the balanced device 200 to the unbalanced device 100, the switching means 30
If the first converter 10 is in the operating state and the second converter 20 is in the high impedance state, and conversely data is transferred from the unbalanced device 100 to the balanced device 200, the second converter The transducer 20 has a function of putting the converter 20 into an operating state and the first converter 10 into a high impedance state.

The operation of this device is as follows. first converter 1
When 0 is in the operating state, the two input/output terminals 201
．． A pair of signal data outputted from the balanced device 200 having a single input/output terminal 102 is converted into single signal data by the first converter 10, and is applied to the unbalanced device 100 having a single input/output terminal 101. The second transducer is now in a high impedance state so there is no signal disruption.

Further, when the second converter 20 is in the operating state, the single signal data output from the unbalanced device 100 having the single input/output terminal 101 is converted into a pair of signal data by the second converter 20. is converted into a pair of input/output terminals 20
1,202. At this time, the first transducer is in a high impedance state, so there is no signal disruption.

FIG. 2 shows a specific circuit diagram of the above-described device. In this embodiment, the first transducer 10 (receiver
) and a second converter 20 (driver), a commercially available IC chip (receiver/driver t<-DS 3695 manufactured by National Semiconductor, USA) is used. Here, the description "+5" indicates connection to a DC 5Vm source, and "G" indicates grounding. Further, resistors R1 to R5 are connected to each signal line.

The display of each signal line is as follows.

Di driver in DO driver out DE driver enable RI receiver in RO receiver out RE receiver enable switching means 30 is provided with a control terminal 31 . When this control terminal 31 is grounded, the first converter 10 becomes operational and the second converter 20 becomes a high impedance state. Conversely, if a voltage of 5V is applied to the control terminal 31,
The second transducer 20 is in operation and the first transducer 10
becomes a high impedance state.

When operating the first converter 10, do as follows:
A signal is transmitted from device 200 to device 100.

(1) When transferring logic “true”, terminal 201 is r
Since the signal is at HJ level and the terminal 202 is at rLJ level, the first converter 10 outputs rLJ and a bell. Terminal 101
The rLJ level of is logical "true".

(2) When transferring logic “false”, terminal 201 is r
Since the terminal 202 is at the LJ level and the rHJ level, the first converter 10 outputs the rHJ level. Terminal 101
The rHJ level of is logical "false".

When operating the second converter 20, do the following:
A signal is transmitted from device 100 to device 200.

(1) When transferring logic “true”, terminal 101 is r
Since it is at the LJ level, the second converter 20 is connected to the terminal 202.
The rLJ level is applied to the terminal 201, and the rHJ level is applied to the terminal 201.

This is a logical "truth".

(2) When transferring logic “false”, 61101 is r
Since it is at HJ level, the second converter 20 is connected to the terminal 202.
The rHJ level is applied to the terminal 201, and the rLJ level is applied to the terminal 201.

This is logically "false".

As described above, the transfer direction can be changed depending on the voltage value applied to the terminal 31, making it possible to transfer signals in both directions.

FIG. 3 is a circuit diagram of a specific embodiment in which the SCSI unbalanced/balanced converter according to the present invention is applied to data transfer between a host computer and a sublimation transfer printer.

The embodiment shown in FIG. 2 is a circuit for transferring a 1-bit signal, but in reality, an 8-bit data signal and other control signals are transferred on the SCSI bus. Therefore, in an actual circuit, it is necessary to use the circuits shown in FIG. 2 in parallel as many as the required number of signal lines. In the circuit of FIG. 3, the connector 110 shown on the left side is a 5C3I connector of a sublimation transfer printer as a target, and the connector 210 shown on the right side is a SCSI connector of a host computer as an initiator. Both are 50-pin connectors, but connector 11
0 is an unbalanced type, and connector 210 is a balanced type. In the figure, the signal line name is written next to the pin number of the connector. The unbalanced connector 110 has only 8 data signal lines from DBO to DB7, but the balanced connector 210 has 16 data signal lines each, which is twice as many. is provided. Transducers UOO~U marked in the center
O8 and U10 to U17 are each constituted by the IC chip DS3695 shown in FIG. The wiring between these IC chips and each connector is
As shown in the circuit diagram in the figure. However, the wiring for the 2nd bin and 3rd pin (switching control input terminal) of the IC chip DS3695 shown in FIG. 2 is unique to the circuit shown in FIG. 3. That is, for the eight converters UOI to UO8 used for data signal transfer, NA
A switching@control input terminal is connected to the output terminal of the ND gate 32 (using a 74AS00 IC chip). Therefore, by the output of NAND gate 32,
The direction of data transfer will be controlled. However,
One input terminal of this NAND gate 32 always has 5V.
is given, and the other input terminal is connected to connector 11.
It is connected to the 50th bin of 0, and the 110 output of the sublimation transfer printer is given. After all, the direction of data signal transfer on this SCS I bus is controlled by the sublimation transfer printer's I10 output. In other words, if the !10 output is "in", data transfer from the host computer to the printer is not possible. and the I10 output is “
If "Out", data is transferred from the printer to the host computer. In this way, this 5C3I bus will operate as expected.

On the other hand, converters UIO to U1 used for transferring various control signals
7, its switching input control terminal is connected to a +5v power supply or grounded.

This is because, unlike data signals, the direction of signal transfer for control signals is determined to be one or the other. Therefore, the control signals BSY, MSG, C/D are transferred from the printer to the host computer.

Converter UIO, U13゜U1 that transfers REQ, Ilo
5. U16. For U17, + is connected to the switching input control terminal.
Control signal ACK, R9T, which gives 5v and is transferred from the host computer to the printer.

Transducer U11.transferring SEL. U12. Regarding U14, the switching input terminal is grounded.

Above, a specific example of connecting a host computer and a sublimation transfer printer using a SCSI bus has been described, but in short, the present invention is capable of connecting an unbalanced SCSI device and a balanced SCSI device. It does not matter what kind of equipment it is connected to. For example, it can be used for connections between a host computer and various external storage devices such as magnetic disks, magnetic tapes, and optical disks, or for connections between host computers and various input/output devices such as scanners and various printers. It can also be used for. In addition, the IC chip used is the DS36 shown in the example.
It is not limited to 95.

〔Effect of the invention〕

As described above, according to the present invention, two converters are arranged in parallel between the unbalanced 5C8I device and the balanced SCSI device, and these are switched for use.
It becomes possible to interconnect CSI devices.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the basic configuration of an unbalanced/balanced converter for SCS I according to the present invention, FIG. 2 is a specific circuit diagram of the converter shown in FIG. 1, and FIG. FIG. 2 is a circuit diagram of a specific example in which the converter shown in FIG. 1 is applied to data transfer between a sublimation transfer printer and a host computer. 10... first converter, 20... second converter, 3
0...Switching means, 100...Device equipped with unbalanced SCSI, 200...Device equipped with balanced SCSI,
300...SCSI unbalanced/balanced converter.

Claims (1)

[Claims] A converter for connecting between a device equipped with an unbalanced SCSI and a device equipped with a balanced SCSI to transfer data between the two devices, the converter comprising: a positive input terminal; and a negative input terminal, and an output terminal that outputs a signal based on a difference between signals applied to both input terminals, and each of the two input terminals is provided with the balanced SCSI. The output terminal is connected to a pair of balanced SCSI input/output terminals in the device equipped with the unbalanced SCSI, and the output terminal is connected to the unbalanced SCSI input/output terminal in the device equipped with the unbalanced SCSI.
A first converter connected to an SI input/output terminal, an input terminal, and two output terminals, a positive output terminal and a negative output terminal, and a difference determined based on a signal input from the input terminal. The two output terminals each have a function of outputting two signals having a
a second converter connected to two balanced SCSI input/output terminals, the input terminal being connected to the unbalanced SCSI input/output terminal;
when the data is transferred from the unbalanced SCSI to the balanced SCSI, the first converter is in an operational state and the second converter is in a high impedance state;
a switching means having a function of putting the second converter in an operating state and putting the first converter in a high impedance state when the data is transferred to the unbalanced SCSI converter. /Balanced converter.