JP3155749B2 - Signal processing device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an interface using a SCSI signal between an information processing device such as a computer and a peripheral device such as a printer and a scanner.

[Prior Art] A SCSI signal includes a single-ended signal and a differential signal.
Conventionally, there are two types. Conventionally, a small system uses a single-ended signal, and a large system uses a differential signal.

[Problems to be Solved by the Invention] However, since the above-mentioned two types of SCSI signals are not compatible, conventionally, there is no flexibility in increasing a small system or freely combining both systems. Did not.

Therefore, a signal processing device that relays two types of SCSI signals with compatibility is desired.

In this case, if the SCSI signal is driven by one device, it is not possible to determine whether or not another device is being driven, so that a malfunction may occur.

[Means for Solving the Problems] To solve the above problems, according to the present invention, there is provided a signal processing device for relaying two different types of SCSI buses which are not directly connected to each other. When a data bit designating a specific device is driven on one of the two SCSI buses, data bit driving means for driving the data bit on the other of the two SCSI buses;
When the busy signal is driven / stopped on one of the SCSI buses, the busy signal is driven / stopped on the other of the two SCSI buses, and when the selection signal is driven on one of the two SCSI buses, A signal drive unit for driving the other selection signal and the busy signal of the two SCSI buses, and a transfer source device and a transfer destination device connected to different ones of the two SCSI buses, Transfer control means for transmitting a signal indicating a transfer request and permission and a data signal from one of the two SCSI buses to the other.

FIG. 1 is a block diagram of an information processing system using a SCSI signal relay device to which the present invention is applied. In FIG. 1, reference numerals 1 and 2 denote SCSI buses which are not directly connected to each other.
Is a differential signal using the RS485 standard, and 2 is a TTL single-ended signal. 3 is a SCSI signal relay device, 4 to 9 are
Devices connected to the SCSI bus operate as initiators or targets, and all have different ID numbers.

2 to 4 show the internal circuit of the SCSI signal relay device 3, 10 and 11 are SCSI connectors using differential signals, and 12 to 29 are TTL level differential signals of RS485 standard. Receivers that convert to signals, 30-47 are transmitters that convert TTL level signals to RS485 standard differential signals, 48-65 are TTL
A driver that converts a level signal to a TTL open collector signal, 66 to 83 are Schmitt inverters that input open collector signals, 84 to 86 are D flip-flops,
87 is a 4-input AND gate, 88 is a 3-input NAND gate, 89 to 90
Is a 2-input AND gate, 91 to 96 are D flip-flops, 97
Is a 2-input OR gate, 98 is a 3-input NAND gate, 99 is 4-input
AND gate, 100 is a 2-input NOR gate, 101 is a 2-input AND gate, 102 is a 2-input NOR gate, 103 is a 2-input AND gate,
104 to 106 are D flip-flops, 107 is a three-input NAND gate, 108 is a two-input NAND gate, 109 to 110 are D flip-flops, 111 is a three-input NAND gate, 112 is a two-input NAND gate, and 113 to 115 are two inputs. OR gate, 116 is JK flip-flop, 117-118 are 3-input NAND gates, 119-121 are inverters, 122-127 are 2-input NAND gates, 128-129 are 3 inputs
NAND gates, 130-133 are D flip-flops, 134-137
Is a 2-input AND gate, 138 to 145 are D flip-flops, 1
46, 148, 150, 152 are 2-input NOR gates, 147, 149, 15
1 and 153 are 2-input AND gates, 154 to 157 are D flip-flops, 158 to 161 are D flip-flops, 162 to 165 are 2-input AND gates, 166 to 173 are D flip-flops, 174 and 17
6, 178 and 180 are 2-input NOR gates, 175, 177, 179 and 181 are 2-input AND gates, 182 to 185 are D flip-flops, 186
188 to D flip-flops, 189 to 191 two-input AND gates, 192 to 197 D flip-flops, 198, 200, and 202 two-input NOR gates, 199, 201, and 203 two-input AND gates, 2
04 to 206 are D flip-flops, 207 to 210 are D flip-flops, 211 to 214 are 2-input AND gates, 215 to 222 are D flip-flops.
Flip-flops, 223, 225, 227, 229 are 2-input NOR gates, 224, 226, 228, 230 are 2-input AND gates, 231-223
4 is a D flip-flop.

Next, how the respective phases of bus-free, arbitration, selection, reselection, and information transfer in the above configuration change will be described.

The bus free phase means that the selection (SEL) and busy (BSY) signals are not driven for more than 400 ns.

The arbitration phase means that the BSY is detected within 800ns or more and within 1.8μs after detecting the bus free phase.
Drive the signal and data bits for its SCSI ID,
After a lapse of 2.2 μs or more, the SCSI device that determines the priority of the bus use right request by comparing the value on the data bus and detects that a data bit having a higher priority than itself is being driven, The SCSI device that stops driving all bus signals within 800 ns after the other SCSI device drives the SEL signal and drives the highest priority data bit drives the SEL signal. By doing so, it means waiting for at least 1.2 μs from acquiring the right to use the bus, further driving the SEL signal, and starting the transition to the selection phase or reselection phase.

The selection phase is a phase for selecting a target from the initiator, and has acquired the bus right
At least 1.2 µs after the SCSI device (initiator) starts to drive the SEL signal, drives the target and the initiator's own SCSI ID data bit on the data bus, and then waits at least 90 ns before stopping the BSY signal drive Wait for more than 400 ns before the target drives the BSY signal, while the target drives the SEL and its own data bus bit corresponding to its SCSI ID for more than 400 ns, and the BSY signal and I / O When it detects that the signal is not being driven, it recognizes that it is selected, and within 200 μs, responds by driving the BSY signal, and the initiator responds within 90 ns after detecting the BSY signal. This means stopping the driving of the SEL signal.

The reselection phase is a phase for selecting the initiator side from the target side. After a lapse of 1.2 μs or more after the SCSI device (target) that has acquired the bus right starts driving the SEL signal, the I / O on the data bus is started. O
Drive the signal, the initiator, and the target's own SCSI ID.After that, wait at least 90 ns, stop driving the BSY signal, and wait 400 ns or more, and then start the BSY signal.
Wait until the signal is driven, while the initiator detects that the data bit corresponding to the SEL signal, I / O signal, and its own SCSI ID is driven and the BSY signal is not driven for 400 ns or more. Then, it recognizes that it is selected and responds to the target by driving the BSY signal within 200 μs.
After driving the BSY signal after detecting the signal, 90ns
SEL signal drive will be stopped within
After detecting that the driving of the EL signal has stopped,
Stopping driving of a signal is referred to.

The information transfer phase is a collective term for the command, data, status, and message phases, and is classified into in (target → initiator) and out (initiator → target) according to the information transfer direction. The target side is holding,
The transfer of information is a transfer request signal driven by the target
A which is a response signal driven by the REQ signal and the initiator
Controlled by the CK signal. One-byte information transfer is performed by one set of REQ and ACK signals. There are two types of transfer control methods, an asynchronous mode and a synchronous mode, depending on the difference between the REQ signal and the ACK signal and the response confirmation method.

The asynchronous mode transfer is a method of controlling the transfer while mutually confirming the REQ signal and the ACK signal, and can be used in all information transfer phases. When the I / O signal is driven, information on the bus is transferred from the target to the initiator. The target drives the REQ signal after the value of the data bus is determined. The initiator takes in the value of the data bus and drives the ACK signal to respond. The target holds the value of the data bus until the ACK signal is driven, and stops driving the REQ signal when the ACK signal is driven.
The initiator stops driving the ACK signal after stopping driving the REQ signal. After confirming that the driving of the ACK signal has been stopped, the target proceeds to transfer the next byte. On the other hand I /
When the O signal is not driven, information on the data bus is transferred from the initiator to the target. The target drives the REQ signal and requests the initiator for information transfer. The initiator sends the requested type of information onto the data bus and then drives the ACK signal. The target stops driving the REQ signal by taking in the data on the data bus. The initiator holds the value of the data bus until it detects that the driving of the REQ signal has stopped. When the driving of the REQ signal stops, the driving of the ACK signal also stops. After detecting that the drive of the ACK signal has stopped, the target proceeds to a transfer request for the next byte. This is an asynchronous mode transfer.

On the other hand, synchronous mode transfer is a transfer method that can be used only in the data phase. The transfer cycle of REQ and ACK signals and the number of offsets that can send REQ continuously without ACK response are set between the initiator and target. This is a high-speed data transfer direction in which a plurality of bytes are transferred at a time.

Although the data is transferred according to the above-described SCSI protocol, even when the SCSI signal relay device of the present invention is used,
The entire two logically integrated SCSI buses are
We must be able to adhere to the SI rules.

FIG. 5 is a diagram showing the mode transition. When the two SCSI buses operate in an integrated manner, the mode in which the SCSI signal relay device 3 of FIG.
It is shown in the figure. If only the BSY signal of the SCSI bus 1 in the first bus free phase and then the arbitration phase is driven (turned on), the next SCSI bus 2
When only the BSY signal is turned on, the next SCSI bus 1 and 2
When both are turned on, a reselection phase when there is a target on the further SCSI bus 1, a selection phase when there is an initiator on the further SCSI bus 1, and a reselection phase when there is an initiator on the SCSI bus 1 Selection phase, more SC
A reselection phase when a target is present on the SI bus 2; an information transfer phase when an initiator and target are present on the SCSI bus 1;
Information transfer phase when target exists on SCSI bus 1 and initiator exists on SCSI bus 2;
The information transfer phase can be divided into an information transfer phase when a target exists on the bus 2 and an initiator on the SCSI bus 1, and an information transfer phase when an initiator and a target exist on the last SCSI bus 2.

 An example of a specific operation will be described below.

In the first operation, the SCSI device 6 shown in FIG.
Drives the BSY signal on bus 1 and data bit 4 which is its own ID, and then SCSI device 9
Drives the BSY signal on bus 2 and data bit 6, which is its own ID. As a result, the SCSI device 9 acquires the bus right and
Drives the SEL signal on bus 2, thereby causing SCSI device 6
Stops driving the BSY signal and data bit 4 on the SCSI bus 1, and the SCSI device 9 drives the data bit 2 on the SCSI bus 2 and then stops driving the BSY signal. ID = 2
SCSI device 5 has BSY of SCSI bus 1 as target
The SCSI device 9 drives the signal, and the SCSI device 9 stops driving the SEL signal on the SCSI bus 2 to complete the selection phase. As a result, information transfer between the SCSI devices 9 and 5 is performed using the SCSI bus and the SCSI bus 2, and after the transfer is completed, the SCSI device 5 stops driving the BSY signal on the SCSI bus 1 and enters the bus free state. FIG. 6 shows a state in which the above process is observed at the input section of the SCSI signal relay device. The solid line shown in gray is
Each SCSI signal is not driven by the driver and transmitter of the SCSI signal repeater, H level indicates that it is driven by an external SCSI device, and L level indicates that it is not driven from anywhere. , The solid line in black indicates that each SCSI signal is being driven by the driver or transmitter of the SCSI signal repeater (at this time, whether or not an external SCSI device is being driven depends on the SCSI signal repeater. I can't confirm). The dashed line shows that the time during which the drive is repeatedly turned on and off is omitted, and the gray dashed line does not drive the SCSI signal repeater, but is turned on and off externally. The black dashed line indicates that the driver or transmitter of the SCSI signal relay device may be turned on and off (it is not clear whether it is turned on or off externally). Absent).

In the second operation, the SCSI device 6 transmits the BSY of the SCSI bus 1
Driving the signal and data bit 4 which is its own ID, then
The SCSI device 9 uses the BSY signal and its own I as the initiator.
D drives data bit 6, which results in SCSI device 9 acquiring the bus right and driving the SEL signal on SCSI bus 2 so that SCSI device 6 drives the BSY signal on SCSI bus 1 and data bit 4. And SCSI device 9 drives data bit 3 of SCSI bus 2 and then BSY
Stop the signal. The SCSI device 8 with ID = 3 drives the BSY signal on the SCSI bus 2 as a target and receives
The CSI device 9 stops driving the SEL signal on the SCSI bus 2 and the selection phase ends. As a result SCSI bus 2
Transfer information between SCSI devices 9 and 8 using only
After the transfer is completed, the SCSI device 8 stops driving the BSY signal on the SCSI bus 2 and enters the bus free state. FIG. 7 shows a state in which the above process is observed at the input section of the SCSI signal relay device.

As a third operation, the SCSI device 6 performs BSY of the SCSI bus 1
Driving the signal and data bit 4 which is its own ID, then
SCSI device 9 as target BSY signal and own ID
, And as a result, the SCSI device 9 acquires the bus right and drives the SEL signal of the SCSI bus 2,
As a result, the SCSI device 6 stops driving the BSY signal and the data bit 4 on the SCSI bus 1, and further the SCSI device 9
Drives I / O signal and data bit 3 of SCSI bus 2, then B
Stop the SY signal. The SCSI device 8 with ID = 3 drives the BSY signal on the SCSI bus 2 as an initiator, and in response, the SCSI device 9 drives the BSY signal on the SCSI bus 2 and stops driving the SEL signal. Thereafter, the SCSI device 8 stops driving the BSY signal on the SCSI bus 2. This ends the reselection phase. As a result, information transfer between the SCSI devices 9 and 8 is performed using only the SCSI bus 2, and after the transfer is completed, the SCSI device 9 stops driving the BSY signal on the SCSI bus 2 and enters a bus free state. FIG. 8 shows a state in which the above process is observed at the input section of the SCSI signal repeater.

As a fourth operation, the SCSI device 6 performs the BSY of the SCSI bus 1
Driving the signal and data bit 4 which is its own ID, then
SCSI device 9 as target BSY signal and own ID
, And as a result, the SCSI device 9 acquires the bus right and drives the SEL signal of the SCSI bus 2,
As a result, the SCSI device 6 stops driving the BSY signal and the data bit 4 on the SCSI bus 1, and further the SCSI device 9
Drive the I / O signal and data bit 2 of the SCSI bus 2 and then stop the BSY signal. The SCSI device 5 with ID = 2 drives the BSY signal on the SCSI bus I as an initiator, and in response, the SCSI device 9 drives the BSY signal on the SCSI bus 2 and stops driving the SEL signal. Then SCSI device 5
Stops driving the BSY signal on the SCSI bus 1. This ends the selection phase. As a result, SCSI bus 1
The SCSI device 9 transfers information between the SCSI devices 9 and 5 using the SCSI bus 2 and the SCSI device 9 after the transfer is completed.
The driving of the signal is stopped and the bus enters a free state. FIG. 9 shows a state in which the above process is observed at the input section of the SCSI signal repeater.

Among the states shown in FIG. 5, the states not shown in FIGS. 6 to 9 are all indicated by the fact that the SCSI bus 1 and the SCSI bus 2 are symmetrical and that the BSY signal is not driven simultaneously in the arbitration phase. Therefore, the description is omitted.

Next, the internal operation of the SCSI signal relay device at the time of the first operation will be described with reference to the timing chart of FIG.

First, the SCSI connected to SCSI bus 1 at the timing
The device 6 drives the BSY signal and the data bit 4, and the output BSY-1I of the receiver 22 and the output DB4-1I of the receiver 16 transition to H. Therefore, the Q output of the D flip-flop 84 becomes H when the CLK changes from L to H. The AND gate 87 goes high when all inputs go high, and the D output of the D flip-flop 91 goes high when the next CLK goes from low to high. As a result, the driver 58 is turned on, and the BSY signal of the SCSI bus 2 on the side where the device is not driven is driven.
SY-2I becomes H. Similar D flip-flops 158, 166
Becomes high, the driver 52 is turned on, the data bit 4 of the SCSI bus 2 is driven, and DB4-2I goes high. At the subsequent timing, this time the SC connected to SCSI bus 2
The SI device 9 drives the BSY signal and the data bit 6, and outputs the output BSY-2I of the inverter 76 and the output DB6-2I of the inverter 72.
Transitions to H. The Q output of D flip-flop 104 is CLK
Becomes H when L changes from L to H, the Q output of the D flip-flop 91 is H, and the output of the OR gate 97 is H.
Since the output of the NAND gate 98 also becomes L, the output of the AND gate 99 remains L and the output of the D flip-flop 92 cannot become H. On the other hand, D flip-flop 18
4, the Q output of 171 becomes H, the transmitter 36 drives the data bit 6 of the SCSI bus 1, and sets DB6-1-1 to H. Next, at one timing, the SCSI device 9 recognizes that the priority of its own ID is the highest, and the output SEL-2I of the inverter 80 becomes H to drive the SEL signal. Therefore D
The Q outputs of the flip-flops 105 and 94 become H, turn on the transmitter 44 and drive the SEL signal of the SCSI bus 1, and SEL-1I becomes H. At the same time that the Q output of the D flip-flop 94 goes high, the output a of the NAND gate 108 goes low for one clock period in which the next CLK goes from low to high and the output of the D flip-flop 109 goes low. AND gate
The output of 87 is L, the output of NAND gate 98 and AND gate 99 is H
, The Q output of the D flip-flop 91 becomes L, and the Q output of the D flip-flop 92 becomes H. Therefore, the transmitter 40 turns on and the driver 58 turns off. As a result, the BSY signal on the SCSI bus 1 that did not hold the bus right in the arbitration phase is driven by the SCSI signal repeater.

If the Q output of the D flip-flop 91 remains H, the SCSI device 6 that has not taken the bus right stops driving the BSY signal and the data bit 4 of the SCSI bus 1 at the next timing of 2. First, D flip-flop
Since the Q outputs of 84 and 91 become L, the output of the OR gate 97 becomes L and the outputs of the NAND gate 98 and the AND gate 99 become H, the Q output of the D flip-flop 92 becomes H, and the transmitter 40 is turned on. , The BSY signal of the SCSI bus 1 is driven. In other words, D flip-flops whose Q output is H are interchanged in the same manner.
Occurs when the BSY signal is not driven for one clock, which violates the SCSI standard.

In this circuit, since the BSY signal of the SCSI device that has acquired the bus right is detected, the drive state of the BSY signal does not change in both SCSI buses 1 and 2 at the timing of 2.
When SEL-2I becomes H, the output of the OR gate 113 becomes H, and the Q output of the JK flip-flop 116 becomes H when the next CLK changes from L to H. Next, when the SCSI device 9 drives the data bit 2 of the SCSI bus 2 at the timing of 3 in order to select a target, the output of the inverter 68 becomes H and the Q outputs of the D flip-flops 156 and 143 become H
Then, the transmitter 32 is turned on and drives the data bit 2 of the SCSI bus 1. The SCSI device 9 stops driving the BSY signal on the SCSI bus 1 at the timing of 4, and enters the selection phase. As a result, the output of the inverter 76 becomes L, the output of the D flip-flop 104 becomes L when the CLK signal changes from L to H, and the D flip-flop 92 also changes to L by changing the next CLK signal from L to H, The transmitter 40 is turned off, and the driving of the BSY signal on the SCSI bus 1 stops.
When the SCSI device 5 recognizes that the self is selected as the target because the SEL signal and its own ID = 2 are driven and the BSY signal and the I / O signal are not driven, the SCSI device 5 issues the SCSI bus at timing 1 1 of the BSY signal, so that the output BSY-1I of the receiver 22 becomes H,
The Q outputs of the flip-flops 84 and 91 become H and the driver 58
Is turned on, and the BSY signal of the SCSI bus 2 is driven. The SCSI device 9 confirms that the target has responded to the BSY signal, and stops driving the SEL signal at two timings. As a result, the selection phase ends and the information transfer phase starts. In the information transfer phase, the Q output of the JK flip-flop 116 becomes H, the output of the OR gate 113 becomes L, and the output of the inverter 119 becomes H.
Becomes L, the Q output of the D flip-flop 215 becomes H, and the output REQ-1I of the receiver 28 is output to the driver 64 without delay of the clock. Similarly, the Q output of the D flip-flop 218 becomes H, and the output ACK-2I of the inverter 77 is output to the transmitter 41 without delay of the clock. That is, in the information transfer mode, the RE
Q and ACK signals that require high speed
Can communicate to SCSI bus. Similarly, the data signal requires high speed, but the data signal is slightly complicated because the transmission direction differs depending on the I / O signal output from the target. In this case, the target SCSI device 5 is
Since it is on SCSI bus 1 and outputs the BSY signal,
When the Q output BSY-2E of the flip-flop 91 is H and the data transfer direction is out (initiator → target), the Q output I / O-2E of the D flip-flop 95 is L, in (target → initiator). In case of I / O-2
When E goes high and out, only the output of the NAND gate 124 goes low, so the output of the NAND gate 127 goes high, and the Q output of the JK flip-flop 116 and the output of the inverter 119 go high. The output h of 129 becomes L. In the case of IN, only the output of the NAND gate 123 becomes L, the output of the NAND gate 126 becomes H, and the Q output of the JK flip-flop 116 and the output of the inverter 119 become H, so that the output g of the NAND gate 128 becomes L. Becomes For this reason, D flip-flops 139, 141, 143, 145, 16
The Q outputs of 7, 169, 171, 173, and 193 become H, and the SC on which the target exists from the SCSI bus 2 on which the initiator exists
The data is transmitted to the SI bus 1 without delay of the clock. Similarly, in the D flip-flops 138, 140, and 14
The Q outputs of 2, 144, 166, 168, 170, 172, and 192 become H, and data is transmitted from the SCSI bus 1 where the target is present to the SCSI bus 2 where the initiator is present without any clock delay. When the information transfer phase ends, the SC
The SI device 5 stops driving the BSY signal, releases the SCSI bus, and enters the bus free phase. Since the SEL signal and BSY signal are not all driven, the OR of the OR gates 113, 114, and 115
The Q output of the gate goes low, and the Q output of the JK flip-flop 116 goes low when CLK goes from low to high. Therefore, the outputs of f, g, and h all return to H again. Then wait for the next arbitration phase.

Next, the internal operation of the SCSI signal repeater at the time of the second operation will be described with reference to the timing chart of FIG.

At the first timing, the SCSI device 6 connected to the SCSI bus 1 drives the BSY signal and the data bit 4, and the output BSY-1I of the receiver 22 and the output DB4-1I of the receiver 16 transition to H. Therefore, the Q output of the D flip-flop 84 becomes H when the CLK changes from L to H. The AND gate 87 goes high when all inputs go high, and the D output of the D flip-flop 91 goes high when the next CLK goes from low to high. As a result, the driver 58 is turned on, and the SCSI bus 2
BSY is driven. Similarly, D flip-flops 158 and 166
Of the SCSI bus 2 is driven, and the data bit 4 of the SCSI bus 2 is driven. At the subsequent timing, the SCSI device 9 connected to the SCSI bus 2 drives the BSY signal and the data bit 6, and the output BSY-2 of the inverter 76.
I and the output DB6-2I of the inverter 72 transition to H. The Q output of the D flip-flop 104 goes high when the CLK changes from L to H, but the Q output of the D flip-flop 91 goes high, the output of the OR gate 97 goes high, and the output of the NAND gate 98 goes high. Since the output also becomes L, the output of the AND gate 99 remains L and the output of the D flip-flop 92 cannot become H. On the other hand, the Q outputs of the D flip-flops 184 and 171 become H, and the transmitter 36 drives the data bit 6 of the SCSI bus 1. Then, at one timing, the SCSI device 9
Recognizes that the ID has the highest priority, and drives the SEL signal, so that the output SEL-2I of the inverter 80 becomes H. Therefore, the Q outputs of the D flip-flops 105 and 94 are H
Then, the transmitter 44 is turned on, and the SEL signal of the SCSI bus 1 is driven. At the same time as the Q output of the D flip-flop 94 goes high, the output a of the NAND gate 108 goes low during one clock period when the next CLK goes from low to high and the output of the D flip-flop 109 goes low. When the output of the gate 87 is L, the outputs of the NAND gate 98 and the AND gate 99 are H, the Q output of the D flip-flop 91 is L, and the Q output of the D flip-flop 92 is H. Therefore, the transmitter 40 turns on and the driver 58 turns off. As a result, the BSY signal on the SCSI bus 1 that did not hold the bus right in the arbitration phase is driven by the SCSI signal repeater.

If the Q output of the D flip-flop 91 remains H, the SCSI device 6 that has not taken the bus right stops driving the BSY signal and the data bit 4 of the SCSI bus 1 at the next timing of 2. First, D flip-flop
Since the Q outputs of 84 and 91 become L, the output of the OR gate 97 becomes L and the outputs of the NAND gate 98 and the AND gate 99 become H, the Q output of the D flip-flop 92 becomes H, and the transmitter 40 is turned on. The BSY signal of the SCSI bus 1 is driven. In other words, D flip-flops whose Q output is H are interchanged in the same manner.
Occurs when the BSY signal is not driven for one clock, which violates the SCSI standard.

In this circuit, since the BSY signal of the SCSI device that has acquired the bus right is detected, the drive state of the BSY signal does not change in both SCSI buses 1 and 2 at the timing of 2.
When SEL-2I goes high, the output of the OR gate 113 goes high, the Q output of the JK flip-flop 116 goes low, and the next CLK goes low.
It becomes H when it changes from H to H. Next, when the SCSI device 9 drives the data bit 3 of the SCSI bus 2 at the timing of 3 to select a target, the output DB3-2I of the inverter 69 becomes H, and the Q outputs of the D flip-flops 157 and 145 become H. Then, the transmitter 33 is turned on and drives the data bit 3 of the SCSI bus 1. SCSI device 9
At timing 4, the drive of the BSY signal on the SCSI bus 2 is stopped, and the operation enters the selection phase. As a result, the output of the inverter 76 becomes L, and when the CLK signal goes from L to H, D
The output of the flip-flop 104 is L, and the next CLK signal is L
Going high, the D flip-flop 92 goes low,
The transmitter 40 is turned off, and the driving of the BSY signal on the SCSI bus 1 stops. When the SCSI device 8 confirms that the SEL signal and its own ID are driven and the BSY signal and the I / O signal are not driven and that the SCSI device 8 is selected as the target, the SCSI device 8 transmits the BSY signal of the SCSI bus 2 at timing 1. And the output BSY-2I of the inverter 76 becomes H and D
The Q outputs of the flip-flops 104 and 92 become H, the transmitter 40 is turned on, and the BSY signal of the SCSI bus 1 is driven. S
The CSI device 9 confirms that the target has responded to the BSY signal, and stops driving the SEL signal at the timing of 2. As a result, the selection phase ends and the information transfer phase starts. In the information transfer phase, the Q output of the JK flip-flop 116 becomes H, the output of the OR gate 113 becomes L, and the output of the inverter 119 becomes H.
The output e of 17 becomes L, the Q output of the D flip-flop 216 becomes H, and the output REQ-2I of the inverter 82 is outputted to the transmitter 46 without delay of the clock. At the same time, the Q output of the D flip-flop 217 becomes H, and the output ACK-1I of the receiver 23 is output to the driver 59 without delay of the clock. However, since both the target and the initiator are actually connected to the SCSI bus 2, the REQ signal is transmitted to the SCSI bus 1, but the ACK signal is not transmitted to the SCSI bus 1. When the initiator and the target are present on the same SCSI bus side, the high-speed transmission function of REQ and ACK is not useful. Similarly, it is explained that the high-speed transmission function of the data signal is not useful, but there is no side effect. In this case, the target is on SCSI bus 2 and BS
Since the Y signal is output, the Q of the D flip-flop 92
When the output BSY-1E is H and the data transfer direction is out (initiator → target), the Q output I / O-1E of the D flip-flop 96 is L, and when the data transfer direction is in (target → initiator), I / O When O-1E goes high and out, only the output of the NAND gate 122 goes low, so the NAND gate 126
Is high, and the output g of the NAND gate 128 is low because the Q output of the JK flip-flop 116 and the output of the inverter 119 are high. NAND gate 1 for in
Since only the output of 25 becomes L, the output of the NAND gate 127 becomes H. Since the Q output of the JK flip-flop 116 and the output of the inverter 119 become H, the output h of the NAND gate 129 becomes L. Therefore, the Q of the D flip-flops 138, 140, 142, 144, 166, 168, 170, 172, 192
The output becomes H, and the data is transmitted from the SCSI bus 1 to the SCSI bus 2 without delay. Actually, since the initiator exists on the SCSI bus 2, the driver of the SCSI signal relay device is not driven, so that there is no adverse effect on the data transfer between the SCSI buses 2. Similarly, the D flip-flops 139, 141, 143, 145, 167, 169, 171, 17
3, the Q output of 193 becomes H, and SCSI bus 2
The data is transmitted as is without delay of the clock. In this case, the transmitter of the SCSI signal relay device is turned on, but since there is no device transferring information on the SCSI bus 1, this also has no side effect. When the information transfer phase is completed, the SCSI device 8 stops driving the BSY signal, and
Release the bus and enter the bus free phase. SEL signal, B
Since all SY signals are not driven, OR gates 113, 1
The Q output of the OR gates 14 and 115 becomes L, and the Q output of the JK flip-flop 116 becomes L when CLK changes from L to H.
Therefore, the outputs of e, g, and h all return to H again. Then wait for the next arbitration phase.

Next, the internal operation of the SCSI signal repeater at the time of the third operation will be described with reference to the timing chart of FIG.

First, the SCSI connected to SCSI bus 1
The device 6 drives the BSY signal and the data bit 4, and the output BSY-1I of the receiver 22 and the output DB4-1I of the receiver 16 transition to H. Therefore, the D flip-flop 84 outputs
When it goes from H to H, the Q output goes to H. The AND gate 87 goes high when all inputs go high, and the D output of the D flip-flop 91 goes high when the next CLK goes from low to high. As a result, the driver 58 is turned on, and the BSY signal of the SCSI bus 2 is driven. Similarly, D flip-flop 1
The Q outputs of 58 and 166 become H, the driver 52 is turned on, and the data bit 4 of the SCSI bus 2 is driven. At the subsequent timing, the SCSI device 9 connected to the SCSI bus 2
The BSY signal and the data bit 6 are driven, and the output BSY-2I of the inverter 76 and the output DB6-2I of the inverter 72 transition to H. The Q output of the D flip-flop 104 becomes H when CLK changes from L to H, but the Q output of the D flip-flop 91 becomes H, the output of the OR gate 97 becomes H, and the NAND
Since the output of the gate 98 also becomes L, the output of the AND flip-flop 92 can become H while the output of the AND 99 remains L. On the other hand, the Q outputs of the D flip-flops 184 and 171 become H, and the transmitter 36 drives the data bit 6 of the SCSI bus 1. Next, at one timing, the SCSI device 9 recognizes that the priority of its own ID is the highest, and the output SEL-2I of the inverter 80 becomes H to drive the SEL signal.
Therefore, the Q outputs of the D flip-flops 105 and 94 become H, turn on the transmitter 44 and drive the SEL signal of the SCSI bus 1. At the same time as the Q output of the D flip-flop 94 becomes H, the next CLK changes from L to H and the D flip-flop 1
During one clock when the output of 09 becomes L, the NAND gate 108
Of the AND gate 87 is L, NAN
When the outputs of the D gate 98 and the AND gate 99 become H, the Q output of the D flip-flop 91 becomes L, and the Q output of the D flip-flop 92 becomes H. Therefore, transmitter 40
Turns on and driver 58 turns off. As a result, the BS of SCSI bus 1 that did not hold the bus right in the ardration phase
The Y signal is driven by the SCSI signal repeater.

If the Q output of the D flip-flop 91 remains H, the SCSI device 6 that has not taken the bus right stops driving the BSY signal and the data bit 4 of the SCSI bus 1 at the next timing of 2. First, D flip-flop
Since the Q outputs of 84 and 91 become L, the output of the OR gate 97 becomes L, and the outputs of the NAND gate 98 and the AND gate 99 become H, the Q output of the D flip-flop 92 becomes H and the transmitter 40 is turned on. Then, the BSY signal of the SCSI bus 1 is driven. In other words, the D flip-flops whose Q outputs are H are interchanged, but when they are interchanged, a timing occurs in which the BSY signal of the SCSI bus 1 is not driven for one clock, which violates the SCSI rules. .

In this circuit, the BSY signal of the SCSI device that has taken the bus right is detected.
No change occurs in the driving state of the BSY signal in both cases. When SEL-2I goes high, the output of the OR gate 113 goes high, and the Q output of the JK flip-flop 116 goes high when the next CLK changes from low to high. Next, when the SCSI device 9 drives the I / O signal and the data bit 3 of the SCSI bus 2 at the timing of 3 to select the initiator, the outputs DB3-2I and I / O-2I of the inverters 69 and 83 become H level. Becomes D
The Q outputs of the flip-flops 157 and 145, 106 and 96 become H, and the transmitters 33 and 47 are turned on to drive the data bit 3 of the SCSI bus 1 and the I / O signal. The SCSI device 9 stops driving the BSY signal at timing 4 and enters the reselection phase. As a result, the output BSY-2I of the inverter 76 becomes L, the output of the D flip-flop 104 becomes L when the CLK signal changes from L to H, and the D flip-flop 92 also changes to L when the next CLK signal changes from L to H. , The transmitter 40 is turned off and the driving of the BSY signal on the SCSI bus 1 is stopped. When the SCSI device 8 recognizes that the SEL signal, the I / O signal, and the data bit of its own ID are driven, and that the BSY signal is not driven, the SCSI device 8 selects itself as the initiator, and the SCSI device 8 issues the SCSI bus at one timing. 2, the output of the inverter 76 goes high, the Q outputs of the D flip-flops 104 and 92 go high, the transmitter 40 is turned on, and the BSY signal on the SCSI bus 1 is driven. S
The CSI device 9 confirms that there is a response of the BSY signal from the initiator, drives the BSY signal as a target,
The drive of the SEL signal is stopped at the timing of 2. The initiator confirms that the driving of the SEL signal has stopped
Stop driving the SY signal. Thus, during the reselection phase, the BSY signal is first driven by the initiator, and finally the target is driven. In other words, the SCSI signal repeater sends the I / O signal of the SCSI bus that drives the SEL signal to SE.
When the drive of the L signal stops, it is determined that the drive is in the reselection phase, and if the transfer direction of the BSY signal is different from the transfer direction of the I / O signal, the transfer direction of the BSY signal is changed to I / O. Make it the same as the signal transfer direction. More specifically, when the Q outputs of the D flip-flops 94 and 96 are H, the driving of the SEL signal is stopped, and when the Q output of 94 becomes L, the output becomes H. b is 1
During the clock, it goes low, so the output of AND gate 87 goes low. Since the output of the OR gate 97 was L, the output of the NAND gate 98 did not change at H even if b became L,
The output of gate 99 also remains H. That is, the Q output of the D flip-flop 91 remains L, and the Q output of the 92 remains H. This ends the reselection phase and enters the information transfer phase. In the information transfer phase, the Q output of the JK flip-flop 116 becomes H, the output of the OR gate 113 becomes L, and the output of the inverter 119 becomes H.
Becomes low, the Q output of the D flip-flop 216 becomes high, and the output of the inverter 82 is output to the transmitter 46 without any clock delay. Similarly, the Q output of the D flip-flop 217 becomes H, and the output of the receiver 23 is output to the driver 59 without any delay of the clock. But in fact, both the target and initiator are SCSI
Since it is connected to the bus 2, the REQ signal is transmitted to the SCSI bus 1, but the ACK signal is not transmitted to the SCSI bus 1. When the initiator and the target are present on the same SCSI bus side, the high-speed transmission function of REQ and ACK is not useful. Similarly, it is explained that the high-speed transmission function of the data signal is not useful, but there is no side effect. In this case, since the target exists on the SCSI bus 2 and outputs the BSY signal, the Q output BSY-1 of the D flip-flop 92 is output.
When E is H and the data transfer direction is out (initiator → target), the Q output I / O-1E of the D flip-flop 96 is L, and when the data transfer direction is in (target → initiator), I / O-1E. Becomes H, and when out, NAND
Since only the output of the gate 122 becomes L, the output of the NAND gate 126 becomes H, and since the Q output of the JK flip-flop 116 and the output of the inverter 119 become H, the NAND gate 128 becomes
Is L. In the case of IN, only the output of the NAND gate 125 becomes L, so the output of the NAND gate 127 becomes H, and J
Since the Q output of the K flip-flop 116 and the output of the inverter 119 are H, the output h of the NAND gate 129 is L. Therefore, the D flip-flop 13
The Q outputs of 8, 140, 142, 144, 166, 168, 170, 172, and 192 become H, and data is transmitted from the SCSI bus 1 to the SCSI bus 2 without delay. Actually, since the initiator exists on the SCSI bus 2, the driver of the SCSI signal relay device is not driven, and does not have a side effect on the data transfer between the SCSI buses 2. Similarly, in the D flip-flops 139, 141, 143, 145, 167, 169, 171, 173,
The Q output of 193 becomes H, and the data is transmitted from the SCSI bus 2 to the SCSI bus 1 without delay. In this case, the transmitter of the SCSI signal repeater turns on,
Since there is no device transferring information on SCSI bus 1,
This also has no side effects. When the information transfer phase ends, the SCSI device 8 stops driving the BSY signal, releases the SCSI bus, and enters the bus free phase. Since the SEL signal and BSY signal are not all driven, OR gates 113, 114, 11
The Q output of the OR gate of 5 becomes L, and the JK flip-flop 1
The 16 Q outputs go to L when CLK goes from L to H. Therefore, the outputs of e, g, and h all return to H again. Then wait for the next arbitration phase.

Next, the internal operation of the SCSI signal relay device in the case of the operation of FIG. 4 will be described with reference to the timing chart of FIG.

First, the SCSI connected to SCSI bus 1
The device 6 drives the BSY signal and the data bit 4, and the output BSY-1I of the receiver 22 and the output DB4-1I of the receiver 16 are high.
Transitions to. Therefore, the Q output of the D flip-flop 84 becomes H when the CLK changes from L to H. AND gate 87
Becomes high when all inputs are high, and the D flip-flop 91 outputs Q when the next CLK changes from low to high.
The output becomes H. As a result, the driver 58 is turned on, and the BSY signal on the SCSI bus 2 is driven. Similarly, the Q outputs of the D flip-flops 158 and 166 become H, the driver 52 is turned on, and the SCSI
Data bit 4 of bus 2 is driven. At the subsequent timing, this time the SCSI device 9 connected to the SCSI bus 2
Drives the BSY signal and the data bit 6, and the output BSY-2I of the inverter 76 and the output DB6-2I of the inverter 72 transition to H. The Q output of the D flip-flop 104 becomes H when CLK changes from L to H, but the Q output of the D flip-flop 91 becomes H, the output of the OR gate 97 becomes H, and the NAND
Since the output of the gate 98 also becomes L, the output of the AND gate 99 remains L and the output of the D flip-flop 92 cannot become H. On the other hand, the Q outputs of the D flip-flops 184 and 171 become H, and the transmitter 36 drives the data bit 6 of the SCSI bus 1. Then, at one timing, the SCSI device 9 recognizes that its ID has the highest priority,
The output SEL-2I of the inverter 80 is high to drive the SEF signal.
Becomes As a result, the Q outputs of the D flip-flops 105 and 94 become H, and the transmitter 44 is turned on, and the SEL of the SCSI bus 1 is turned on.
Drive signals. At the same time that the Q output of the D flip-flop 94 becomes H, the next CLK changes from L to H and the output of the D flip-flop 109 becomes L for one clock.
Since the output a of the gate 108 becomes L, the output of the AND gate 87 becomes L, and the outputs of the NAND gate 98 and the AND gate 99 become H, whereby the Q output of the D flip-flop 91 becomes L and the D flip-flop 92 becomes Is H. Therefore, the transmitter 40 turns on and the driver 58 turns off. This means that SCSI did not take the bus right in the arbitration phase
The BSY signal on the bus is driven by the SCSI signal relay device.

If the Q output of the D flip-flop 91 remains H, the SCSI device 6 that has not taken the bus right stops driving the BSY signal and the data bit 4 of the SCSI bus 1 at the next timing of 2. First, D flip-flop
Since the Q outputs of 84 and 91 become L, the output of the OR gate 97 becomes L and the outputs of the NAND gate 98 and the AND gate 99 become H, the Q output of the D flip-flop 92 becomes H, and the transmitter 40 is turned on. Then, the BSY signal of the SCSI bus 1 is driven. In other words, the D flip-flops whose Q output is H are interchanged, but when they are exchanged, the SCSI bus 1
A timing occurs in which the BSY signal is not driven for one clock, which violates the SCSI standard.

In this circuit, since the BSY signal of the SCSI device that has acquired the bus right is detected, the drive state of the BSY signal does not change in both SCSI buses 1 and 2 at the timing of 2.
When SEL-2I goes high, the output of the OR gate 113 goes high.
And the Q output of the JK flip-flop 116 is
It becomes H when it changes from H to H. Next, in order to select the initiator, the SCSI device 9 drives the I / O signal and the data bit 2 of the SCSI bus 2 at the timing of 3, and the outputs of the inverters 68 and 83 become H and the D flip-flop 156
And 143, 106 and 96 output H, and the transmitter 32
And 47 are turned on to drive the data bit 2 of the SCSI bus 1 and the I / O signal. SCSI device 9 is BSY at timing 4.
Stop driving the signal and enter the reselection phase. As a result, the output of the inverter 76 changes to L, and when the CLK signal changes from L to H, the output of the D flip-flop 104 changes to L, and the next CLK signal changes from L to H, so that the D flip-flop 92 also changes. L, transmitter 40
It turns off, and the driving of the BSY signal on the SCSI bus 1 stops. The SCSI device 5 is driven by the SEL signal, the I / O signal, and its own ID,
When the BSY signal is not driven and it recognizes that it has been selected as the initiator, it drives the BSY signal of the SCSI bus 1 at the timing of 1, and the output BSY-1I of the receiver 22 becomes H, Flip-flops 8
The Q output of 4, 91 becomes H, the driver 58 is turned on, and the BSY signal of the SCSI bus 2 is driven. The SCSI device 9 confirms that there is a response of the BSY signal from the initiator, drives the BSY signal as a target,
Stop driving the EL signal. The initiator stops driving the BSY signal after confirming that the driving of the SEL signal has stopped. As described above, in the reselection phase, the BSY signal is first driven by the initiator and finally driven by the target. That is, when the driving of the SEL signal is stopped, if the I / O signal of the SCSI bus driving the SEL signal is driven, the SCSI signal relay device determines that the reselection phase is in progress, and if the BSY signal is When the transfer direction is different from the transfer direction of the I / O signal, the transfer direction of the BSY signal is set to be the same as the transfer direction of the I / O signal. More specifically, when the Q outputs of the D flip-flops 94 and 96 are H, the driving of the SEL signal is stopped, and when the Q output of 94 becomes L, the output becomes H. b becomes L for one clock, so that the output of the AND gate 87 becomes L. N
Since the output of the AND gate 98 is H and the D flip-flop 104 is H, the output of the AND gate 99 is H, and C
When LK changes from L to H, the Q output of the D flip-flop 91 changes to L and the Q output of 92 changes to H. As a result, the reselection phase ends and the information transfer phase starts. In the information transfer phase, the Q output of the JK flip-flop 116 becomes H, the output of the CR gate 113 becomes L, and the output of the inverter 119 becomes H, so that the output e of the NAND gate 117 becomes L, The output becomes H, and the output REQ-2I of the inverter 82 is output to the transmitter 46 without delay of the clock. Similarly, the Q output of the D flip-flop 217 becomes H, and the output ACK-1I of the receiver 23 is output to the driver 59 without delay of the clock. That is, in the information transfer mode, signals requiring high speed such as REQ and ACK can be transmitted to the SCSI bus of the other party at high speed. Similarly, the data signal requires high speed, but the data signal is the I / O output from the target.
Since the transmission direction differs depending on the signal, it becomes slightly complicated. In this case, since the target exists on the SCSI bus 2 and outputs the BSY signal, the Q output of the D flip-flop 92
When BSY-1E is H and the data transfer direction is out (initiator → target), the Q output I / O-1E of the D flip-flop 96 is L, and when the data transfer direction is in (target → initiator), I / O When -1E goes high and out, only the output of the NAND gate 122 goes low, so the NAND gate 126
Is high, and the Q output of the JK flip-flop 116 and the output of the inverter 119 are high.
The output g of the gate 128 becomes L. In the case of in, only the output of the NAND gate 125 becomes L, so the output of the NAND gate 127 becomes H
Since the Q output of the JK flip-flop 116 and the output of the inverter 119 are H, the output h of the NAND gate 129 becomes L. For this reason, the Q output of the D flip-flops 138, 140, 142, 144, 166, 168, 170, 172, and 192 goes H, and the SCSI bus 1 in which the initiator exists
Is transmitted to the SCSI bus 2 where the target exists without delay of the clock. Similarly, in the in D
Flip-flops 139, 141, 143, 145, 167, 169, 17
The Q outputs of 1, 173 and 193 become H, and the SCSI bus 2 where the target exists and the SCSI bus 1 where the initiator exists
The data is transmitted as it is without delay of the clock.
When the information transfer phase is completed, the SCSI device 9
Stops driving the Y signal, releases the SCSI bus, and enters the bus free phase. Since the SEL signal and the BSY signal are not all driven, the Q output of the OR gates of the OR gates 113, 114, and 115 becomes L, and the Q output of the JK flip-flop 116 becomes CLK low.
From H to L. Therefore, the outputs of e, g, and h all return to H. Then wait for the next arbitration phase.

As described above, different SCSI buses can be configured as if they were one SCSI bus. Specifically, SCSI devices that use differential signals and single-ended signals
SCSI devices can be used together.

Further, according to the present invention, three or four independent SCSI buses can be used as one bus by using two or three SCSI signal repeaters as shown in FIG. 10 or FIG. it can. This allows each SCSI device to use a single-ended signal and to transmit the SCSI signal using a differential signal.

As described above, by using the SCSI signal relay device, it is possible to convert a single-ended SCSI device used for a short distance into a differential signal capable of transmitting a signal over a relatively long distance. This eliminates the need to create two types of interfaces, single-ended and differential, and can quickly respond to changes in the system.

[Effects of the Invention] As described above, according to the present invention, when a device connected to a SCSI bus acquires a bus right and drives a selection signal, the other SCSI bus of a type different from the SCSI bus is used. The busy signal is driven by a signal processing device that relays two SCSI buses, so that different types of two SCSI buses can be relayed without inadvertent relaying of signals. This has the effect. This also makes it easy to construct a system by combining different types of SCSI devices.

[Brief description of the drawings]

FIG. 1 is a block diagram of an information processing system using a SCSI signal relay device to which the present invention is applied, FIGS. 2 to 4 are diagrams showing a circuit configuration of the SCSI signal relay device, and FIG. 6 to 9 are timing charts of respective signals, and FIGS. 10 and 11 are diagrams showing other system configuration examples. In the figure, 1 and 2 are SCSI buses, 3 is a SCSI signal relay device, 4 to
9 is a device, 10 and 11 are connectors, 12 to 29 are receivers,
30 to 47 are transmitters, and 48 to 65 are drivers.

──────────────────────────────────────────────────続 き Continued on front page (58) Field surveyed (Int.Cl. ⁷ , DB name) G06F 3 / 00,13 / 36

Claims (1)

(57) [Claims] 1. A signal processing device for relaying two different types of SCSI buses that are not directly connected to each other, wherein a data bit designating a specific device is driven on one of the two SCSI buses. Then, data bit driving means for driving the data bit on the other of the two SCSI buses, and when the busy signal is driven / stopped on one of the two SCSI buses, the two SCSI buses Signal driving means for driving / stopping the busy signal on the other side and driving the selection signal and the busy signal on the other of the two SCSI buses when the selection signal on one of the two SCSI buses is driven And when a transfer source device and a transfer destination device are connected to different ones of the two SCSI buses, a signal indicating a transfer request and permission and a data signal are transmitted to the two SCSI buses.
A signal processing device having transfer control means for transmitting from one side of the SI bus to the other side.