iECM-86 COMMANDS

5.4.2BYTE Commands

There are four forms for the BYTE commands:

BYTE byte_address

BYTE byte_address = byte_value

BYTE byte_address TO byte_address

BYTE byte_address TO byte_address = byte_value

All of these commands can be used whether or not the user’s program is running.

BYTE byte_address This form is used to examine and then possibly change one or more sequential BYTE variables. When this command is invoked, iECM- 86 displays the byte_address in hexadecimal notation and the value of the BYTE in the default base, then waits for an input from you.

You can respond with a carriage return character, an ESC character, or a numeric value. A carriage return terminates the command. An ESC results in the display of the next sequential BYTE variable. If a numeric value is entered, the BYTE variable is set to this value and the iECM-86 again waits for input. At this point, you can respond only with an ESC or carriage return. As before, the ESC displays the next sequential BYTE and the carriage return terminates the command.

BYTE byte_address = byte_value

This form is used to set an individual BYTE variable without first checking its current value. When invoked, this command sets the BYTE variable at byte_address to byte_value.

BYTE byte_address TO byte_address

This form is used to display a region of memory as a sequence of BYTE variables. When this command is invoked, iECM-86 starts by displaying the current default base and then a series of lines showing the contents of the selected memory region. The next line starts with a hexadecimal display of the address of the next BYTE variable to be displayed, followed by the display of up to 16 bytes of memory as BYTE variables in the default base. A new line start whenever 16 bytes of memory have been displayed on the line. The command terminates when all of the BYTE variables in the selected range have been displayed. During lengthy displays, you can stop the output to the console by pressing the space bar. You can resume the display by pressing the space bar a second time. You terminate the command by entering a carriage return.

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Intel 80L188EB, 80L188EC, 80L186EB, 80L186EC Byte Commands, Byte byteaddress = bytevalue, Byte byteaddress to byteaddress

80L188EB, 80C188EC, 80C188EB, 80L186EB, 80C186EB specifications

The Intel 80L188EC, 80C186EC, 80L186EC, 80C186EB, and 80L186EB microprocessors represent a significant evolution in Intel's 16-bit architecture, serving various applications in embedded systems and computing during the late 1980s and early 1990s. These microprocessors are designed to offer a blend of performance, efficiency, and versatility, making them suitable for a range of environments, including industrial control, telecommunications, and personal computing.

The Intel 80L188EC is a member of the 186 family, notable for its low-power consumption and integrated support for a range of peripheral devices. It operates at clock speeds of up to 10 MHz and features a 16-bit architecture, providing a balance of processing power and energy efficiency. The 80C186EC, on the other hand, is a more advanced version, offering enhanced performance metrics with faster clock speeds and improved processing capabilities, making it ideal for applications that require more computational power.

The 80L186EC shares similarities with the 80L188EC but is enhanced further for various low-power applications, especially where battery life is crucial. With a maximum clock speed of 16 MHz, it excels in scenarios demanding energy-efficient processing without sacrificing performance.

In contrast, the 80C186EB and 80L186EB are optimized versions that bring additional features to the table. The 80C186EB operates at higher clock speeds, coupled with an extended instruction set, enabling it to handle more complex tasks and run sophisticated software. These enhancements allow it to serve well in environments that require reliable performance under load, such as data acquisition systems or advanced control systems.

The 80L186EB is tailored for specific low-power scenarios, integrating Intel's sophisticated low-power technologies without compromising on speed. Utilizing advanced process technologies, these chips benefit from reduced heat output and extended operating life, a significant advantage in embedded applications.

Overall, these microprocessors showcase Intel's commitment to innovation in 16-bit processing, marked by their varying capabilities and power profiles tailored to meet the demands of diverse applications, from industrial systems to consumer electronics. Their legacy continues to influence subsequent generations of microprocessor designs, emphasizing performance, energy efficiency, and versatile applications in computing technology. As such, the Intel 80C186 and 80L188 families play a crucial role in understanding the evolution of microprocessor technology.