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view src/adc_lightsensor.asm @ 19:06e19a880df6
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author | heinrichsweikamp |
---|---|
date | Wed, 03 Jul 2013 11:51:46 +0200 |
parents | 11d4fc797f74 |
children | 0e1723f2761e |
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;============================================================================= ; ; File adc.asm ; ; ; Copyright (c) 2011, JD Gascuel, HeinrichsWeikamp, all right reserved. ;============================================================================= ; HISTORY ; 2011-08-08 : [mH] moving from OSTC code #include "ostc3.inc" #include "math.inc" #include "wait.inc" #include "eeprom_rs232.inc" sensors CODE wait_adc: movwf ADCON0 nop bsf ADCON0,1 ; start ADC wait_adc2: btfsc ADCON0,1 ; Wait... bra wait_adc2 return global get_battery_voltage get_battery_voltage: ; starts ADC and waits until fnished bsf adc_running ; =1: The ADC is in use movlw b'00100000' ; 2.048V Vref+ -> 1LSB = 500µV movwf ADCON1 movlw b'00011001' ; power on ADC, select AN6 rcall wait_adc movff ADRESH,batt_voltage+1 ; store value movff ADRESL,batt_voltage+0 ; store value bcf ADCON0,0 ; power off ADC ; Multiply with 2,006 to be excact here... ; bcf STATUS,C ; rlcf xA+0,F ; ; rlcf xA+1,F ; x2 ; movff xA+0,batt_voltage+0 ; store value ; movff xA+1,batt_voltage+1 movlw LOW lithium_36v_low movwf sub_a+0 movlw HIGH lithium_36v_low movwf sub_a+1 movff batt_voltage+0,sub_b+0 movff batt_voltage+1,sub_b+1 call subU16 ; sub_c = sub_a - sub_b ; Battery is 3,6V (>lithium_36v_low?) btfss neg_flag bra get_battery_voltage4 ; No, use 1,5V bsf battery_is_36v ; Yes, set flag (Cleared in power-on reset only!) ; Check if the battery is near-dead already movlw LOW lithium_36v_empty movwf sub_a+0 movlw HIGH lithium_36v_empty movwf sub_a+1 call subU16 ; sub_c = sub_a - sub_b ; Battery is not dead yet (>lithium_36v_empty?) btfsc neg_flag bra get_battery_voltage2 ; Yes, battery is still ok ; Battery is probably dead very soon ; Set ">=24Ah used" into battery gauge registers movlw .128 movff WREG,battery_gauge+5 get_battery_voltage2: ; Use 3,6V battery gauging mode movff battery_gauge+5,xC+3 movff battery_gauge+4,xC+2 movff battery_gauge+3,xC+1 movff battery_gauge+2,xC+0 ; battery_gauge:6 is nAs ; devide through 65536 ; devide through 364 ; Result is in percent of a 2,4Ah Battery movlw LOW .364 movwf xB+0 movlw HIGH .364 movwf xB+1 call div32x16 ; xC:4 / xB:2 = xC+3:xC+2 with xC+1:xC+0 as remainder movff xC+0,lo ; Limit to 100 movlw .100 cpfslt lo movwf lo ; lo will be between 0 (Full) and 100 (empty) movf lo,W sublw .100 movwf lo get_battery_voltage3: movlw .100 cpfslt lo movwf lo ; lo will be between 100 (Full) and 0 (empty) movf batt_percent,W cpfsgt lo ; keep batt_percent on the lowest value found movff lo,batt_percent ; store value btfsc battery_is_36v ; but always use computed value for 3,6V battery movff lo,batt_percent ; store value bcf adc_running ; =1: The ADC is in use return get_battery_voltage4: ; Use 1,5V battery voltage mode ; Use approximation (batt_voltage:2-aa_15v_low)/4 = lo movff batt_voltage+0,sub_a+0 movff batt_voltage+1,sub_a+1 movlw LOW aa_15v_low movwf sub_b+0 movlw HIGH aa_15v_low movwf sub_b+1 call subU16 ; sub_c = sub_a - sub_b bcf STATUS,C rrcf sub_c+1 rrcf sub_c+0 ; /2 bcf STATUS,C rrcf sub_c+1 rrcf sub_c+0 ; /4 movff sub_c+0,lo bra get_battery_voltage3 ; Check limits and return global get_ambient_level get_ambient_level: ; starts ADC and waits until finished btfsc adc_running ; ADC in use? return ; Yes, return movlw b'00000000' ; Vref+ = Vdd movwf ADCON1 movlw b'00011101' ; power on ADC, select AN7 rcall wait_adc movff ADRESH,ambient_light+1 movff ADRESL,ambient_light+0 bcf ADCON0,0 ; power off ADC ; ambient_light:2 is between 4096 (direct sunlight) and about 200 (darkness) ; First: Devide through 16 bcf STATUS,C rrcf ambient_light+1 rrcf ambient_light+0 bcf STATUS,C rrcf ambient_light+1 rrcf ambient_light+0 bcf STATUS,C rrcf ambient_light+1 rrcf ambient_light+0 bcf STATUS,C rrcf ambient_light+1 rrcf ambient_light+0 ; Result: ambient_light:2/16 ; Now, make sure to have value between ambient_light_low and ambient_light_max movlw .254 tstfsz ambient_light+1 ; >255? movwf ambient_light+0 ; avoid ADC clipping incfsz ambient_light+0,W ; =255? bra get_ambient_level2 ; No, continue movlw .254 movwf ambient_light+0 ; avoid ADC clipping get_ambient_level2: banksel isr_backup ; Back to Bank0 ISR data movff opt_brightness,isr1_temp btfsc RCSTA1,7 ; UART module on? clrf isr1_temp ; Yes, set temporally to eco mode incf isr1_temp,F ; adjust 0-2 to 1-3 banksel common ; flag is in bank1 movlw ambient_light_max_high ; brightest setting btfsc battery_is_36v ; 3,6V battery in use? movlw ambient_light_max_high_36V ; Yes... banksel isr_backup ; Back to Bank0 ISR data dcfsnz isr1_temp,F movlw ambient_light_max_eco ; brightest setting dcfsnz isr1_temp,F movlw ambient_light_max_medium; brightest setting banksel common ; ambient_light is in Bank1 incf ambient_light+0,F ; +1 cpfslt ambient_light+0 ; smaller then WREG? movwf ambient_light+0 ; No, set to max. banksel isr_backup ; Back to Bank0 ISR data movff opt_brightness,isr1_temp incf isr1_temp,F ; adjust 0-2 to 1-3 movlw ambient_light_min_high ; darkest setting dcfsnz isr1_temp,F movlw ambient_light_min_eco ; darkest setting dcfsnz isr1_temp,F movlw ambient_light_min_medium; darkest setting dcfsnz isr1_temp,F movlw ambient_light_min_high ; darkest setting banksel common ; ambient_light is in Bank1 cpfsgt ambient_light+0 ; bigger then WREG? movwf ambient_light+0 ; No, set to min movff ambient_light+0,max_CCPR1L ; Store value for dimming in TMR7 interrupt return global get_rssi_level get_rssi_level: ; starts ADC and waits until fnished bsf adc_running ; =1: The ADC is in use movlw b'00100000' ; 2.048V Vref+ movwf ADCON1 movlw b'01000101' ; power on ADC, select AN17 rcall wait_adc movff ADRESL,rssi_value bcf ADCON0,0 ; power off ADC bcf adc_running ; =1: The ADC is in use return global reset_battery_pointer reset_battery_pointer: ; Resets battery pointer 0x07-0x0C and battery_gauge:5 clrf EEADRH clrf EEDATA ; Delete to zero write_int_eeprom 0x07 write_int_eeprom 0x08 write_int_eeprom 0x09 write_int_eeprom 0x0A write_int_eeprom 0x0B write_int_eeprom 0x0C banksel battery_gauge+0 clrf battery_gauge+0 clrf battery_gauge+1 clrf battery_gauge+2 clrf battery_gauge+3 clrf battery_gauge+4 clrf battery_gauge+5 banksel common movlw .100 movwf batt_percent return END