imx6 uboot lvds clock
在uboot中添加logo,lvds接口的lcd显示不正常,出现波动。网上说是lvds时钟频率的问题。
使用示波器测量之后,发现频率是60M,而lcd最大频率才46.8M。
因此就需要更改uboot中lvds的时钟,本文介绍lvds的时钟配置。
参考链接:
https://community.nxp.com/docs/DOC-172312
https://community.nxp.com/docs/DOC-93617
https://community.nxp.com/thread/306801
https://community.nxp.com/thread/355690
https://community.nxp.com/thread/378887
https://community.nxp.com/thread/305115
https://community.nxp.com/thread/395103
原理分析
datasheet: IMX6SDLRM
imx6 使用了2个晶振:
外部低频时钟: 32kHz or 32.768kHz
外部高频时钟: 24MHz
LVDS的时钟就是图中LDB_DI0_IPU和LDB_DI0_IPU
18.5.1.3 PLL reference clock
There are several PLLs in this chip.
PLL1 - ARM PLL (typical functional frequency 800 MHz)
PLL2 - System PLL (functional frequency 528 MHz)
PLL3 - USB1 PLL (functional frequency 480 MHz)
PLL4 - Audio PLL
PLL5 - Video PLL
PLL6 - ENET PLL
PLL7 - USB2 PLL (functional frequency 480 MHz)
PLL8 - MLB PLL
18.5.1.3.1 ARM PLL
This PLL synthesizes a low jitter clock from a 24 MHz reference clock. The clock output
frequency for this PLL ranges from 650 MHz to 1.3 GHz. The output frequency is
selected by a 7-bit register field CCM_ANALOG_PLL_ARM[DIV_SELECT].
PLL output frequency = Fref * DIV_SEL/2
CCM_ANALOG_PLL_ARM寄存器
根据寄存器计算:pll0输出范围
24M * 54 / 2 = 648M
24M * 108 / 2 = 1296M
18.5.1.3.3 System PLL
This PLL synthesizes a low jitter clock from the 24 MHz reference clock. The PLL has
one output clock, plus 3 PFD outputs. The System PLL supports spread spectrum
modulation for use in applications to minimize radiated emissions. The spread spectrum
PLL output clock is frequency modulated so that the energy is spread over a wider
bandwidth, thereby reducing peak radiated emissions. Due to this feature support, the
associated lock time of this PLL is longer than other PLLs in the SoC that do not support
spread spectrum modulation.
......
Although this PLL does have a DIV_SELECT register field, it is intended that this PLL
will only be run at the default frequency of 528 MHz.
Analog System PLL Control Register
24M * 20 = 480M
24M * 22 = 528M
18.5.1.4 Phase Fractional Dividers (PFD)
There are several PFD outputs from the System PLL and USB1 PLL.
Each PFD output generates a fractional multiplication of the associated PLL’s VCO
frequency. Where the output frequency is equal to Fvco*18/N, N can range from 12-35.
The PFDs allow for clock frequency changes without forcing the relock of the root PLL.
This feature is useful in support of dynamic voltage and frequency scaling (DVFS). See
CCM Analog Memory Map/Register Definition.
频率最小值:
480M * 18 / 35 = 246M
246M / 7 = 35M
代码更改
board/freescale/mx6q_sabresd/mx6q_sabresd.c
void lcd_enable(void)
{
......
#elif defined CONFIG_MX6DL /* CONFIG_MX6Q */
/*
* IPU1 HSP clock tree:
* osc_clk(24M)->pll3_usb_otg_main_clk(480M)->
* pll3_pfd_540M(540M)->ipu1_clk(270M)
*/
/* pll3_usb_otg_main_clk */
/* divider */
writel(0x3, ANATOP_BASE_ADDR + 0x18);
/* pll3_pfd_540M */
/* divider */
writel(0x3F << 8, ANATOP_BASE_ADDR + 0xF8);
writel(0x10 << 8, ANATOP_BASE_ADDR + 0xF4);
/* enable */
writel(0x1 << 15, ANATOP_BASE_ADDR + 0xF8);
/* ipu1_clk */
reg = readl(CCM_BASE_ADDR + CLKCTL_CSCDR3);
/* source */
reg |= (0x3 << 9);
/* divider */
reg &= ~(0x7 << 11);
reg |= (0x1 << 11);
writel(reg, CCM_BASE_ADDR + CLKCTL_CSCDR3);
/*
* ipu1_pixel_clk_x clock tree:
* osc_clk(24M)->pll2_528_bus_main_clk(528M)->
* pll2_pfd_352M(452.57M)->ldb_dix_clk(64.65M)->
* ipu1_di_clk_x(64.65M)->ipu1_pixel_clk_x(64.65M)
*/
/* pll2_528_bus_main_clk */
/* divider */
//Tony
//1. ---------- 将pll2由528M更改为480M ------------------
reg = readl(ANATOP_BASE_ADDR + 0x34);
reg &= ~(1 << 0); // 24M * 20 = 480M
writel(reg, ANATOP_BASE_ADDR + 0x34);
////////////
//writel(0x1, ANATOP_BASE_ADDR + 0x34); // 24M * 22 = 528M
/* pll2_pfd_352M */
/* disable */
writel(0x1 << 7, ANATOP_BASE_ADDR + 0x104);
/* divider */
//2. ---------更改分频参数为35. 480 * 18 / 35 = 246M ----------
writel(0x3F, ANATOP_BASE_ADDR + 0x108);
writel(0x23, ANATOP_BASE_ADDR + 0x104);
//原来设置 528M * 18 / 21 = 452.57M
// writel(0x3F, ANATOP_BASE_ADDR + 0x108);
// writel(0x15, ANATOP_BASE_ADDR + 0x104);
/* ldb_dix_clk */
/* source */
//3. --------- 选择时钟源, pll2_pfd0 -----------
//ldb_di1_clk_sel Selector for ldb_di1 clock multiplexer
//NOTE: Multiplexor should be updated when both input and output clocks are gated.
//000 pll5 clock
//001 derive clock from PLL2 PFD0
//010 derive clock from PLL2 PFD2
//011 derive clock from mmdc_ch1 clock
//100 derive clock from pll3_sw_clk
//101-111 Reserve
reg = readl(CCM_BASE_ADDR + CLKCTL_CS2CDR);
reg |= (0x9 << 9);
writel(reg, CCM_BASE_ADDR + CLKCTL_CS2CDR);
/* divider */
reg = readl(CCM_BASE_ADDR + CLKCTL_CSCMR2);
reg |= (0x3 << 10);
writel(reg, CCM_BASE_ADDR + CLKCTL_CSCMR2);
/* pll2_pfd_352M */
/* enable after ldb_dix_clk source is set */
writel(0x1 << 7, ANATOP_BASE_ADDR + 0x108);
//ipu1 di1 root clock multiplexer : derive clock from ldb_di1_clk
//ipu1 di0 root clock multiplexer : derive clock from ldb_di0_clk
reg = readl(CCM_BASE_ADDR + CLKCTL_CHSCCDR);
reg &= ~0xE07;
reg |= 0x803;
//ipu1 di1 root clock multiplexer : derive clock from ldb_di1_clk
//ipu1 di0 root clock multiplexer : derive clock from ldb_di0_clk
writel(reg, CCM_BASE_ADDR + CLKCTL_CHSCCDR);
#endif /* CONFIG_MX6DL */
......
Author
Tony Liu
2016-8-23, Shenzhen