1 00:00:00,060 --> 00:00:06,510 So when we consider seeing pricing system, we have a multiple time more than a counter available with 2 00:00:06,510 --> 00:00:12,240 zinc pricing systems, some of them are private to a zinc processing system that basically mean to utilize 3 00:00:12,240 --> 00:00:12,480 them. 4 00:00:12,480 --> 00:00:15,780 We do not need to enable or disable anything. 5 00:00:15,930 --> 00:00:20,160 And some of them could be enabled by going into a configuration. 6 00:00:20,460 --> 00:00:26,580 So first, we'll start with a private diamonds that we have in zinc processing system. 7 00:00:26,580 --> 00:00:34,960 So it includes a washed up timer, which is having a size of 32 bit and also the timer of, say, 32 8 00:00:34,980 --> 00:00:35,420 bit rate. 9 00:00:36,060 --> 00:00:41,400 So this you are locked with half of the ambulance frequency. 10 00:00:41,400 --> 00:00:44,820 That arm is operating at six six seven megahertz. 11 00:00:45,240 --> 00:00:50,880 So both of those resources, which are private two are zinc processing system, will operate at top 12 00:00:50,880 --> 00:00:53,820 of the clock frequency that is 333 megahertz. 13 00:00:54,360 --> 00:00:56,160 So we will first be understanding them. 14 00:00:56,850 --> 00:01:03,600 Some of them, which are also available with zinc processing system, include global timer, which which 15 00:01:03,600 --> 00:01:05,280 is 64 bit in size. 16 00:01:06,090 --> 00:01:08,610 And we also have triple the timer counted. 17 00:01:08,630 --> 00:01:13,620 So to triple timer counters are available, which could generate three Independent.ie timer open. 18 00:01:14,100 --> 00:01:16,760 And the last thing that we have a system would stop them. 19 00:01:16,770 --> 00:01:26,540 So if you just go to the fundamental high block design, so you could see by default and BD, that is 20 00:01:26,550 --> 00:01:26,970 system. 21 00:01:27,820 --> 00:01:28,600 Not anywhere, not. 22 00:01:29,280 --> 00:01:37,830 So to utilize them to purposefully enable them, but by default, the 32 bit timer and 32 bit washed 23 00:01:37,830 --> 00:01:41,260 off timer, which are private to the CPU irony. 24 00:01:41,430 --> 00:01:44,350 So we do not need to do anything to utilize them, right? 25 00:01:44,370 --> 00:01:51,090 So first, we'll proceed with them and then we will be considering PDC, OK, which we need to innovate. 26 00:01:51,120 --> 00:01:59,280 So what we need to do is just to change the Drapkin for our basic block to say, OK, which have you 27 00:01:59,460 --> 00:02:00,420 been enabled now? 28 00:02:00,780 --> 00:02:06,030 Why we are utilizing you to this help us to understand the different things that are happening in our 29 00:02:06,030 --> 00:02:06,860 application rates. 30 00:02:06,860 --> 00:02:13,890 So once rapid is ready, we do not need to specify anything since this boot are already connected, 31 00:02:14,250 --> 00:02:15,930 connected to their respective pin. 32 00:02:16,230 --> 00:02:19,060 We just need to go ahead and to date the bits, right? 33 00:02:19,080 --> 00:02:25,290 This is the first step that we do in and we will do so once bitstream generation is successful, we 34 00:02:25,290 --> 00:02:26,280 just need to. 35 00:02:27,210 --> 00:02:31,950 Export anhydride file, including a bit, and then we need to launch it, right? 36 00:02:32,250 --> 00:02:40,440 So remember, we have 32 bit watchdog timer, 32 bit timer, which are private to a CPU and to utilize 37 00:02:40,440 --> 00:02:46,320 them, we do not need to enable annual functions, so they are by default enumerate. 38 00:02:46,320 --> 00:02:51,180 So we will be understanding how we utilize them in our application.