Jnh, JNV Jump if Overflow Flag is Clear | Intel 80C196NU, 8XC196NP

									INSTRUCTION SET REFERENCE
				Table A-6. Instruction Set (Continued)

Mnemonic					Operation					Instruction Format

JNH	JUMP IF NOT HIGHER (UNSIGNED). Tests
	both the zero flag and the carry flag. If the								JNH	cadd
	carry flag is set and the zero flag is clear,								JNH	cadd
	carry flag is set and the zero flag is clear,								(11010001) (disp)
	control passes to the next sequential								(11010001) (disp)
	control passes to the next sequential
	instruction. If either the carry flag is clear or
	the zero flag is set, this instruction adds to the								NOTE: The displacement (disp) is sign-
	program counter the offset between the end								NOTE: The displacement (disp) is sign-
	program counter the offset between the end									extended to 24 bits.
	of this instruction and the target label,									extended to 24 bits.
	of this instruction and the target label,
	effecting the jump. The offset must be in
	range of –128 to +127.
	if C = 0 OR Z = 1 then
	PC ← PC + 8-bit disp

				PSW Flag Settings
		Z		N	C	V	VT	ST
		—	—		— —	—	—

JNST	JUMP IF STICKY BIT FLAG IS CLEAR. Tests
	the sticky bit flag. If the flag is set, control								JNST	cadd
	passes to the next sequential instruction. If								JNST	cadd
	passes to the next sequential instruction. If								(11010000) (disp)
	the sticky bit flag is clear, this instruction adds								(11010000) (disp)
	the sticky bit flag is clear, this instruction adds
	to the program counter the offset between the
	end of this instruction and the target label,								NOTE: The displacement (disp) is sign-
	effecting the jump. The offset must be in								NOTE: The displacement (disp) is sign-
	effecting the jump. The offset must be in									extended to 24 bits.
	range of –128 to +127.									extended to 24 bits.
	range of –128 to +127.
	if ST = 0 then
	PC ← PC + 8-bit disp

				PSW Flag Settings
		Z		N	C	V	VT	ST
		—	—		— —	—	—

JNV	JUMP IF OVERFLOW FLAG IS CLEAR.
	Tests the overflow flag. If the flag is set,								JNV	cadd
	control passes to the next sequential								JNV	cadd
	control passes to the next sequential								(11010101) (disp)
	instruction. If the overflow flag is clear, this								(11010101) (disp)
	instruction. If the overflow flag is clear, this
	instruction adds to the program counter the
	offset between the end of this instruction and								NOTE: The displacement (disp) is sign-
	the target label, effecting the jump. The offset								NOTE: The displacement (disp) is sign-
	the target label, effecting the jump. The offset									extended to 24 bits.
	must be in range of –128 to +127.									extended to 24 bits.
	must be in range of –128 to +127.
	if V = 0 then
	PC ← PC + 8-bit disp

				PSW Flag Settings
		Z		N	C	V	VT	ST
		—		—	— —	—	—

A-25

Microcontroller, 80C196NU, 8XC196NP specifications

The Intel 8XC196NP and 80C196NU microcontrollers are part of Intel's renowned 16-bit microcontroller series that gained popularity in the 1980s and 1990s for embedded systems applications. Designed for a variety of applications, these microcontrollers are characterized by their robust performance, versatility, and industry-standard architecture.

The 8XC196NP features an enhanced instruction set with over 100 instructions, allowing for efficient code execution. It operates at clock speeds up to 16 MHz, which contributes to improved performance in time-sensitive applications. The microcontroller is equipped with a 16-bit data bus, enabling more efficient data handling compared to its 8-bit predecessors, thus accommodating complex algorithms and large data sets.

In terms of memory architecture, the 8XC196NP supports an addressable memory space of up to 64 KB of program memory and 64 KB of data memory. This configuration provides sufficient space for large applications while ensuring fast data access. The microcontroller includes integrated features such as timers, serial I/O capabilities, and interrupt processing, which enhance its functionality for real-time applications and control mechanisms.

The 80C196NU, on the other hand, is designed for lower power operation, making it suitable for battery-powered devices. This microcontroller maintains similar features to the 8XC196NP while offering advancements that support low-power consumption. The 80C196NU can also function in a range of temperature environments, making it adaptable for industrial applications.

Both the 8XC196NP and 80C196NU support external memory interfacing, allowing designers to expand the system's capability by connecting additional ROM and RAM. This flexibility makes them appealing for developing complex systems, such as motor controls, industrial automation, and consumer electronics.

Another standout feature of these microcontrollers is their built-in debugging capabilities. Intel provided hardware and software tools that enabled developers to test and troubleshoot their applications effectively, reducing the development time and increasing reliability.

Overall, the Intel 8XC196NP and 80C196NU microcontrollers stand out for their dependability, versatility, and performance, contributing significantly to the evolution of embedded system design. Their legacy continues to influence modern microcontroller technology, ensuring their relevance in a wide array of applications today.

Intel 80C196NU, 8XC196NP, Microcontroller manual Jnh, JNV Jump if Overflow Flag is Clear

Models: Microcontroller 80C196NU 8XC196NP

Table A-6. Instruction Set (Continued)

Mnemonic

Operation

Instruction Format

JNH

JNV

JUMP IF OVERFLOW FLAG IS CLEAR.

Microcontroller, 80C196NU, 8XC196NP specifications