DE9421234U1 - Electronic device for operating standard peripherals remote from the personal computer - Google Patents

Description

Description

Electronic device for operating standard peripherals remotely from the personal computer

The standard peripherals of a currently commercially available personal computer consist of a keyboard, a monitor (VGA), as well as a parallel interface and a serial interface for printers, modems and mice, for example. In some applications, it is desired to operate these peripherals away from the personal computer processor, for example to provide remote workstations for a closely coupled multi-computer or multi-processor system compatible with a personal computer. Existing systems that offer this option are based on the extension cable principle (cf. [Onln94]: US 52 76 817; [Plus88]; [Prol95]). Older systems with EGA displays ([Plus88]) only had to transmit digital video and interface signals, but they only offered limited graphics capabilities. In newer systems ([Onln94],[Prol95]) that have comprehensive graphics capabilities, both the analog VGA video signals and the digital interface signals are transmitted using special multi-core cables with coaxial and twisted pair wires, usually with amplifiers in between. However, both the older and the newer systems have the disadvantage that the special connecting cables required are very expensive and inflexible. In addition, in the newer systems, the transmission of the analog video signals over longer distances (e.g. 100 m) results in losses in image quality, which cannot be avoided even by connecting amplifiers; the distances that can be bridged are very limited in these systems [Onln94],[Prol95].

Furthermore, there are methods [Conn87] and circuits [Cypr93], [NCR93], [Vite92] for remote operation of computer peripherals via serial connections and the error detection and error correction devices required for this, for remote operation of computer systems (DE 30 21 679 C2) and for coupling of spatially close and distant computer stations via parallel and serial connections (US 41 70 038), but these methods do not offer hardware compatibility with the conventional architecture of personal computers, which is required for the use of the widely used

operating systems (MS-DOS, Windows, OS/2, etc.) and the huge software inventories for personal computers.

The invention specified in claim 1 is based on the problem of operating conventional peripheral plug-in cards for personal computers away from the processor while maintaining full hardware and software compatibility.

This problem is solved by the features listed in claim 1.

The invention enables the peripheral devices of the personal computer to be operated further away from the processor than before, while maintaining full hardware and software compatibility, eliminating the need to transmit analog (video) signals over longer distances, and enabling the connection to be made using a thin, flexible, easy-to-install and commercially available and therefore inexpensive digital medium (coaxial cable or optical fiber).

The operation of PC peripheral hardware away from the processor allows the spatial proximity of several processors or mainboards and thus the realization of a personal computer multi-computer system using the known inexpensive commercially available PC peripheral hardware that the user may already have.

An advantageous embodiment of the invention is specified in claims 2, 3 and 4:

Regarding protection claim 2: Processor access to the remote peripheral (8) requires the transmission of the information required for this via the transmission medium (5). In the case of read access, the access must first be transmitted to the peripheral and then the read data must be transmitted back to the processor; the processor must wait for the data to be read, the (double) signal runtime via the transmission medium (5) is therefore important for read access to the peripheral. The processor's wait can be reduced in the case of write access to the peripheral if the bandwidth of the transmission medium (5) is adapted accordingly to the bandwidth of the

Bus (3) and if feedback is dispensed with by appropriate design of the error detection and error correction devices; the signal propagation time over the transmission medium only causes a delay in the effect of the write access by one signal propagation time, but does not require any wait cycles of the processor, i.e. write accesses are not slowed down. If the peripherals connected to the remote peripheral bus (7) contain firmware (i.e. software in a read-only memory), it is therefore sensible to copy the contents of this read-only memory into a memory held in the converter device (4) before using the system and to execute the firmware in this memory. In this way, when executing the firmware commands, which requires constant command fetch phases and thus read accesses, the remote peripherals do not have to be accessed for each command. This offers the time advantages known from a cache memory.

Regarding protection claim 3: If the transmission medium (5) is implemented as a single baseband channel, the transmission direction of which is switched as required, this hardware-implemented interrupt polling mechanism allows collision-free half-duplex data transmission. In order to ensure that peripheral interrupts that occur are forwarded to the processor on the mainboard (2) sufficiently quickly, the interrupt status of all peripheral devices (8) is transmitted to the processor with each peripheral read access by the processor together with the read data. If the processor does not carry out any peripheral read access within a minimum time that can be set on the conversion device (4), a special interrupt status read access is automatically carried out by the conversion device (4). If such an interrupt status read access of the conversion device (4) occurs simultaneously with a peripheral read access of the processor (1), the latter has priority and the former does not need to be carried out. This mechanism ensures that the interrupt status read accesses of the conversion device (4) do not adversely affect the throughput of the overall system.

Regarding protection claim 4: When using certain peripherals (8), it is desirable to be able to carry out direct data transfers between the peripherals and the main memory on the mainboard (2) without using the processor (Direct Memory Access, DMA). The initiator for such actions is the processor or the peripherals; the DMA controller on the mainboard carries out the transfer

([Klot94], p. 76ff). The conversion devices (4) and (6) can be designed so that DMA cycles are possible: For the DMA request signal, which must be transmitted from the peripheral (8) to the DMA controller on the mainboard (2), the hardware polling mechanism from claim 3 can be used if the transmission medium (5) is designed as the only baseband channel in half-duplex operation. The DMA cycles carried out by the DMA controller are very similar to CPU memory or IO accesses with regard to the control signals used, so that the implementation does not present any further problems. In other cases it may be desirable for different peripheral units (8) to carry out data transfers between each other without using the processor (bus master transfers). For this, as in the first case, the mainboard's internal DMA controller is used to take control of the bus and stop the processor on the mainboard. In order for the peripheral (8) that initiates the bus master transfer to take control of the bus (7), the conversion device (6) must be designed in such a way that it behaves like the mainboard logic in this case, i.e. address and certain control signals must be switched to input and certain control signals must be generated. In this way, bus master transfers between peripheral units (8) can be carried out via the bus (7) without the data having to be transmitted via the transmission medium (5).

An embodiment of the invention is explained with reference to Figure 1.

It shows

Fig. 1 the device for operating standard peripherals remotely from the personal computer

A working prototype of the invention to demonstrate its effectiveness was realized in the following way:

A standard PC mainboard (2) with an 80486 processor is used as a personal computer, which is equipped with an ISA bus (3).

The converter (4) is connected, which is designed as an ISA bus plug-in card. The converter accepts part of the peripheral accesses of the peripheral address space, namely accesses to the parallel and serial interface card, the VGA video card, the keyboard and the loudspeaker, serializes the information required for the peripheral access and places it on a coaxial cable (5). The parallel/serial converter used (Media Interface Controller NCR 85C266) allows data transmission via coaxial cable up to 100 m long or via fiber optic cable up to 1500 m long [Hewl94] with a transmission rate of up to 260 megabits/second [NCR93]. The transmission medium (5) here consists of two parallel coaxial cables, one for the data transmission from the converter (4) to the converter (6), the other for the opposite transmission direction. The converter (6) is also an electronic circuit in the form of an ISA bus plug-in card that is plugged into a passive ISA bus with three slots. It receives the information arriving via the transmission medium (5) and carries out the original peripheral access on the passive ISA bus (7) by generating the signals and signal sequences required for this. If it is a read access, the read data is serialized by the converter (6) and sent back via the transmission medium (5) to the converter (4), which passes the data on to the processor. In addition to the converter (6), there is a commercially available VGA card and a commercially available plug-in card with parallel and serial interfaces in the passive ISA bus (7); the electronics for controlling the loudspeaker and keyboard were implemented directly in the converter (6).

According to the description in claim 2, a suitably large read/write memory and control electronics were provided in the conversion device (4) for processing the firmware on the VGA video card, which usually does not comprise more than one segment (i.e. 64 KBytes), so that before using the system, the contents of the firmware memory on the VGA video card connected to the remote ISA bus (7) can be read once and written into the memory of the conversion device (4). The electronics prevent further undesired write accesses to this memory through appropriate design. In this way, the VGA firmware can run in the processor-near memory of the conversion device (4). The command fetch phases required to process the firmware, the read accesses

correspond, all of them run without using the transmission medium. This saves the processor the waiting time each time it fetches a command, which corresponds to twice the signal propagation time of the transmission medium (5).

e Furthermore, in the transfer device (4) the described in claim 3

Mechanism for transmitting the interrupt status of the peripheral (8) to the processor (1) is implemented, although in this case separate coaxial cables were used for the respective transmission direction. In this way, the functionality of this mechanism is demonstrated and it can be used without changing the rest of the arrangement.

iQ single-channel baseband transmission medium that can be switched between transmission directions since no collision between opposing data streams can occur.

The transfer rate of the transmission medium (5) in the present example is so high that it exceeds the bandwidth of the bus (3). Write accesses by the processor to the peripherals (8) are implemented in such a way that no feedback occurs, so that write accesses can take place without wait cycles of the processor. The peripheral unit with by far the largest data volume is the graphics card. Accesses to its memory consist of over 90% write accesses ([Klot94], p. 11). Together with the firmware cache memory described in protection claim 2, the loss in throughput caused by the signal propagation time on the transmission medium remains low.

The implementation of an error detection and error correction device as well as DMA capability was omitted in the present prototype.

Literature:

[Conn87]: Connor, Gary; et al.: Pseudoparallel data transfer with 12.5 MByte/s

over 2km, Electronic Information, No.3/1987, p.58-61. 5

[Cypr93]: Cypress Semiconductor Corporation: CY7B923/933 HOTLink Transmitter/Receiver Data Sheet, Rev. 4/15/93, Cypress Semiconductor Corporation, San Jose, California, USA, 1993.

[Hewl94]: Hewlett Packard: Fibre Channel 133MBd and 266MBd Transceivers Data

Sheet, Rev-3, May 1994, Hewlett Packard, 1994.

[Klot94j: Kloth, Axel: PCI and VESA Local Bus: Multimaster systems - memory bus systems - intelligent peripherals, Franzis-Verlag, Munich, 1994. 15

[NCR93]: NCR Corporation: NCR 85C266 Media Interface Controller Data Manual, Rev. 0.5, NCR Corporation, Dayton, Ohio, USA, 1993.

[Onln94]: ON/LINE Computer Products: Lightstone NetPC, Patent US 52 76 817, Rheindorfer Str. 70, 40764 Langenfeld, Germany, 1994.

[Plus88]: Plustec Inc.: PlusTe Multi-User System, Plustec Inc., 5/F 242 Chung Hsiao E. Road, Sec. 5, Taipei, Taiwan, 1988.

[Prol95]: Prologue GmbH: WiNTimes Hardware, Configuration Sheet, Prologue

GmbH, Bunsenstrasse 2a, 64293 Darmstadt, Germany, 1995.

[Vite92]: Vitesse Semiconductor Corporation: G-TAXIchips VSC7101 -4 Data Communications Chipset Data Book, Rev. 1992, Vitesse Semiconductor Corporation, USA, 1992.

Claims (4)

Protection claims 1. Electronic device for operating standard peripherals remotely from the personal computer,
5 characterized, that a conversion device (4), which is designed as a plug-in card for the peripheral bus (3) (ISA, EISA, VESA, PCI or future bus systems) provided by the mainboard (2) of the personal computer (1), brings the desired peripheral access to a serial digital transmission medium (5) which is at least 5 m long, and the external peripheral station (9) provides a bus (7) which is electronically and mechanically similar to the peripheral bus (3) with the aid of a conversion device (6) connected to the transmission medium, so that commercially available PC peripheral plug-in cards (8) can be used there which were originally designed for direct use on the peripheral bus (3). 2. Device according to claim 1,
characterized, that the conversion device (4) is designed in such a way that the firmware contained in the peripheral device (8) used is converted via the transmission medium (5) into a (4) stored memory and can be executed there. 3. Device according to claim 1,
characterized, that interrupts generated by the peripheral (8) are transmitted to the conversion device (4) with each data retransmission of a peripheral read access carried out by the personal computer (1) or by a special interrupt status read access periodically triggered by the conversion device (4) and the corresponding interrupt is triggered by the conversion device on the mainboard (2) of the personal computer (1). 4. Device according to claim 1,
characterized, that the conversion devices (4) and (6) are designed in such a way that DMA transfers between the peripherals (8) and the main memory located on the mainboard (2) can take place using the transmission medium (5), and that bus master transfers between two peripheral units (8) can take place without using the transmission medium (5) can expire.