DE4031366A1 - Electronic scales with processor and digital address circuit - has memory areas distributed according to boundary address - Google Patents

Abstract

An electrical weighing machine has a balance (2) providing an input to a microprocessor (1) that operates with a ROM (6) and RAM (5). The address circuit for coupling the microprocessor to the memories is based upon a comparator and switch (3) together with a memory (4) for the boundary address (X). The comparator operates upon the generated address with that held in the memory (X). The selection of the memories is based upon whether the value (X) is greater or less than the generated address. ADVANTAGE - Allows boundary address for selecting memory to be varied.

Description

The invention relates to an electric scale a processor and with a digital addressing circuit for a memory with a continuous address area (from Neumann structure) for the division of memory addresses of the Processor to physical addresses of at least one RAM memory module and a ROM memory module.

Electric scales of this type are generally known. The digital addressing circuits serve to be restricted microprocessor address space to RAM memory for variable data and on ROM memory for program codes split up. For example, with an address space of 64 kbytes of RAM and 32 kbytes and the same large ROM memory can be controlled. This store however, division is due to the fixed size of the two stores unable to change Requirements of various user programs on the To meet storage requirements flexibly. Some users programs require a lot of ROM memory space Storage of the command sequences, some less; just like that The RAM memory requirement fluctuates depending on the user program.

From DE-PS 24 43 176 is still an exchange baren memory modules built memory known, in which the address assignment via a comparator and switch is made, the switching limit during the Initialization automatically to the storage capacity of the adapts inserted memory modules. This arrangement too can only be changed by exchanging hardware adjust their storage requirements.

The object of the invention is therefore for an electrical Libra specify an addressing circuit that is a variable Division of the addressable memory area into RAM and ROM areas allowed without changing the hardware and it allowed by using larger memory chips available and addressable memory area almost around the Increase factor 2.

According to the invention this is achieved in that the Addressing circuit a comparator and switch as well a memory for a limit address contains that this Memory for the limit address during the program run can be set in software and that the comparator and toggle all addresses less than the limit address, which is assigned a memory chip and all Addresses that are larger than the limit address to the other Allocated memory block.

In the example given above, this means that an address 64 kbyte of microprocessor instead of 32 kbyte RAM and ROM memory modules contain 64 kbytes each be set. By storing a limit address the division into RAM and ROM areas much more closely to the respective program requirements are adjusted, for example by the lower 41 kbyte of RAM and the upper 23 kbyte of ROM to be used. - The advantage of addresses is even greater Switching circuit if in a longer program one after the other different limit addresses can be saved. In one Program part that requires a lot of RAM space becomes high Border address stored and this part of the program itself is saved in the area of the highest addresses in the ROM. If this part of the program has been processed, a lower one is created Border address saved and the Pro  parts of the gram accessible with lower addresses in the ROM, however, there is only a small one for these program parts more RAM area available. - With this variable, Limiting controlled by the program of the microprocessor In the above example, in the extreme case it can almost do that entire ROM with its 64 kbytes and almost all of the RAM with its 64 kbytes can be used, although the addresser 64 kbyte microprocessor space actually only half allowed so much.

Advantageous further developments, refinements and applications endings result from the subclaims.

The invention is based on the schematic Figures described. It shows:

Fig. 1 is a scale with a microprocessor and memory Addressier circuit in a first embodiment,

Fig. 2 shows a scale with a microprocessor and memory addressing circuit in a second embodiment and

Fig. 3 shows a scale with a microprocessor and memory addressing circuit in a third embodiment.

The first embodiment of the electrical scale shown in FIG. 1 consists of a weighing system 2 with a digital signal output, a microprocessor 1 , a ROM memory module 6 and a RAM memory module 5 . The addressing circuit for connecting the microprocessor 1 to the memory modules 5 and 6 consists of a comparator and switch 3 and a memory 4 for a limit address "X". The comparator compares the address coming from the microprocessor 1 via the line 9 with the limit address "x" stored in the memory 4 . If the address is smaller than the limit address "x", the changeover switch is switched over so that the memory address is assigned to the RAM memory module 5 . If, on the other hand, the address is greater than the limit address "x", the switch is switched so that the memory address is assigned to the ROM memory module 6 . The microprocessor 1 has access to the memory 4 for the limit address via the line 7 and can thereby determine the size of the usable ROM and RAM address area. Since the limit address can be set differently by the microprocessor for different subroutines, e.g. B. for a subroutine that is stored in the ROM 6 in the address range from 63 000 ... 64 999, an address range from 0 ... 62 999 in RAM 5 can be addressed. Nevertheless, 6 subroutines can also be stored in the ROM in the address range from 1000 ... 1999, for example. Before calling these subroutines, only the limit address has to be set to 999 (or less) and the processing of these subroutines must have a maximum RAM requirement of 999 bytes. - By alternately setting the limit address, the two memory modules 5 and 6 with their 64 kbytes each can be used almost completely, although the address area of the microprocessor actually only allows the use of one memory module of 64 kbytes.

In FIG. 2, a second embodiment of the electrical balance is shown. The weighing system 12 , the microprocessor 11 and the two memories 15 and 16 are constructed like the corresponding parts of the first embodiment. However, the addressing circuit consists of a comparator and switch 13 with two memories 14 and 18 for storing two limit addresses "x ₁ " and "x ₂ ". Addresses coming from the microprocessor 11 via the line 19 are compared in the comparator and switch 13 with the two limit addresses "x ₁ " and "x ₂ " and all addresses which are smaller than x ₁ or larger than x ₂ become the RAM memory chip 15 assigned, while all addresses between the two limit addresses "x ₁ " and "x ₂ " are assigned to the ROM memory module 16 . Otherwise, this second embodiment works in exactly the same way as the first embodiment. However, the ability to move the second memory area as an area window offers advantages in memory allocation for many cases.

In Fig. 3 shows a third embodiment of the electrical balance is shown. The weighing system 22 and the microprocessor 21 are constructed as in the other configurations. The addressing circuit again contains two memories 24 and 28 for two limit addresses "x ₁ " and "x ₂ ". However, the comparator and switch 23 has three outputs, which lead to the three memory modules 25 , 26 and 20 . The memory 25 is, for. B. a RAM memory, the memory 26 a ROM memory and the memory 20 an EEPROM memory. The comparator and switch 23 now assigns all the addresses coming from the microprocessor 21 via the line 29 to the memory modules as follows: all addresses which are smaller than the lower limit address "x ₁ ", the RAM memory module 25 , all addresses that are between the two limit addresses "x ₁ " and "x ₂ ", the ROM memory module 26 and all addresses that are larger than the upper limit address "x ₂ ", the EEPROM memory module 20th - This configuration means that three different memory blocks can be addressed. Due to the variable, controlled by the program of the microprocessor 21, the setting of the two limit addresses, significantly more memory space can be used than the addressing range of the microprocessor 21 corresponds.

The configurations of the described above Addressing circuit for the electrical scale are self understandable only examples. Of course they can RAM and ROM memory chips may be interchanged when  ROM memory modules can also include EPROM memory modules can be set, or in general other memory construction stones or peripheral modules can be selected. Just like that can be the address that is exactly the same as the stored limit address is and nothing is said about in the examples depending on the expediency of one or the other Memory module can be assigned.

The addressing circuit ( 3 , 4 ; 13 , 14 , 18 ; 23 , 24 , 28 ) is advantageously designed as a customer-specific integrated circuit.

Claims (4)

1.Electric balance with a processor and with a digital addressing circuit for a memory with a continuous address area (von Neumann structure) for dividing memory addresses of the processor into physical addresses of at least one RAM memory module and one ROM memory module, characterized in that the Addressing circuit a comparator and changeover switch ( 3 , 13 , 23 ) and a memory ( 4 , 14 , 24 ) for a limit address contains that this memory ( 4 , 14 , 24 ) for the limit address can be set in software during the program run and that the comparator and switch ( 3 , 13 , 23 ) assigns all addresses that are smaller than the limit address to the one memory module ( 5 , 15 , 25 ) and all addresses that are larger than the limit address to the other memory module ( 6 , 16 , 26 ). 2. Electrical scale according to claim 1, characterized in that the addressing circuit additionally contains a memory ( 18 ) for a second limit address, that this memory ( 18 ) for the second limit address can be set in software during the program run and that the comparator and switch ( 13 ) all addresses that lie between the two border addresses, the one memory chip ( 16 ) and all addresses that are larger than the larger border address or smaller than the smaller border address, the other memory block ( 15 ). 3. Electrical balance according to claim 1, characterized in that the addressing circuit additionally contains a memory ( 28 ) for a second limit address, that this memory ( 28 ) for the second limit address can be set in software during the program sequence, that additionally a third memory module ( 20 ) is present and that the comparator and changeover switch ( 23 ) assigns all addresses that are smaller than the lower limit address to the one memory module ( 25 ), all addresses that lie between the two limit addresses, the second memory module ( 26 ) and assigns all addresses that are larger than the upper limit address to the third memory chip ( 20 ). 4. Electrical balance according to one of claims 1 to 3, characterized in that the digital addressing circuit ( 3 , 4 ; 13 , 14 , 18 ; 23 , 24 , 28 ) is designed as a customer-specific integrated circuit.