00:05 The video discusses three-stage and five-stage pipelines used in ARM processors, explaining what pipelining is and its advantages and resources. 02:25 In a non-pipelined architecture, it takes 9 clock cycles to execute 3 instructions. 04:50 Pipelining increases execution speed by allowing multiple instructions to be processed simultaneously. 07:26 The three stage pipeline executes instructions with a latency of three clock cycles and a throughput of one instruction per cycle. 10:09 Three-stage pipeline in processor 12:31 ARM processor pipeline has three stages - register, decode, and execute. 14:58 The ARM9 processor uses a 5-stage pipeline. 17:33 The processor has a five-stage pipeline.
Clear & Simple explanation. Could you plz do a video, explaining how to select the MCU based on memory and other peripherals specifically for STM32, and also provide guidance on choosing a generic IDE for ARM controllers.
00:05 The video discusses three-stage and five-stage pipelines used in ARM processors, explaining what pipelining is and its advantages and resources.
02:25 In a non-pipelined architecture, it takes 9 clock cycles to execute 3 instructions.
04:50 Pipelining increases execution speed by allowing multiple instructions to be processed simultaneously.
07:26 The three stage pipeline executes instructions with a latency of three clock cycles and a throughput of one instruction per cycle.
10:09 Three-stage pipeline in processor
12:31 ARM processor pipeline has three stages - register, decode, and execute.
14:58 The ARM9 processor uses a 5-stage pipeline.
17:33 The processor has a five-stage pipeline.
Very good explanation sir
Clear & Simple explanation. Could you plz do a video, explaining how to select the MCU based on memory and other peripherals specifically for STM32, and also provide guidance on choosing a generic IDE for ARM controllers.
Great video. To the point!
Super sir
Plz provide these ppt
Ans B
B