view src/adc_lightsensor.asm @ 613:8077ee960199

fix for italian and french language
author heinrichsweikamp
date Wed, 30 Jan 2019 16:27:56 +0100
parents d866684249bd
children b87f23fae743
line wrap: on
line source

;=============================================================================
;
;   File adc.asm														V2.99e
;
;
;   Copyright (c) 2011, JD Gascuel, HeinrichsWeikamp, all right reserved.
;=============================================================================
; HISTORY
;  2011-08-08 : [mH] moving from OSTC code

#include "hwos.inc"
#include "math.inc"
#include "wait.inc"
#include "eeprom_rs232.inc"
#include "i2c.inc"

	extern	reset_battery_internal_only

adc_light		CODE

;=============================================================================

wait_adc:
	movwf	ADCON0
        nop
	nop
	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 finished
	btfss	battery_gauge_available
	bra		get_battery_voltage1			; normal ostc3 hardware

	call	lt2942_get_accumulated_charge
	call	lt2942_get_voltage

	tstfsz	batt_voltage+1					; < 256 mV ?
	bra		get_battery_voltage_noretry		; NO

	; Retry
	call	lt2942_get_accumulated_charge
	call	lt2942_get_voltage

get_battery_voltage_noretry:
	btfsc	divemode
	return									; not in divemode

	bcf		cv_active
	bcf		cc_active
	bcf		LEDr
	bcf		TRISJ,2							; Chrg-Out output
	bsf		CHRG_OUT

	btfss	CHRG_IN
	bra		charge_cc_active

	bcf		CHRG_OUT
	bsf		TRISJ,2							; Chrg-Out high impedance

	WAITMS	d'1'

	btfsc	CHRG_IN
	return
charge_cv_active:
	decfsz	get_bat_volt_counter,F
	return
	movlw	.15
	cpfsgt	batt_voltage+1					; battery voltage >= 16*256mV (4,096V)?
	bra		charge_cc_active				; NO
	bsf		cc_active
	bsf		cv_active
	bsf		LEDr							; indicate charging
	call	lt2942_charge_done				; reset accumulating registers to 0xFFFF
	WAITMS	d'10'
	bcf		LEDr							; indicate charging
	bsf		get_bat_volt_counter,0			; =1
	return

charge_cc_active:
	bsf		cc_active
	bsf		LEDr							; indicate charging
	bcf		CHRG_OUT
	bsf		TRISJ,2							; chrg-Out high impedance
	movlw	.15
	cpfsgt	batt_voltage+1					; battery voltage >= 16*256mV (4.096 V)?
	bra		charge_cc_active2				; NO
	movlw	.81
	cpfslt	batt_voltage+0					; battery voltage >= 80mV (+4096mV from batt_voltage+1)?
	bra		charge_cv_active				; YES
charge_cc_active2:
	movlw	.10
	movwf	get_bat_volt_counter
	return

get_battery_voltage1:
	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 exact 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
	; divide through 65536
	; divide through battery_capacity:2
	; result is in percent
	movff	internal_battery_capacity+0,xB+0
	movff	internal_battery_capacity+1,xB+1
	call	div32x16						; xC:4 = xC:4 / xB:2 with xA 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)

	; use 3.6V battery sensing based on 50 mA load
	; 75%
	movff	batt_voltage+0,sub_b+0
	movff	batt_voltage+1,sub_b+1
	movlw	LOW  lithium_36v_75
	movwf	sub_a+0
	movlw	HIGH lithium_36v_75
	movwf	sub_a+1
	call	subU16							; sub_c = sub_a - sub_b
	btfsc	neg_flag
	bra		get_battery_voltage3a
	movlw	.75
	movwf	lo
get_battery_voltage3a:
; 50%
	movlw	LOW  lithium_36v_50
	movwf	sub_a+0
	movlw	HIGH lithium_36v_50
	movwf	sub_a+1
	call	subU16							; sub_c = sub_a - sub_b
	btfsc	neg_flag
	bra		get_battery_voltage3b
	movlw	.50
	movwf	lo
get_battery_voltage3b:
	; 25%
	movlw	LOW  lithium_36v_25
	movwf	sub_a+0
	movlw	HIGH lithium_36v_25
	movwf	sub_a+1
	call	subU16							; sub_c = sub_a - sub_b
	btfsc	neg_flag
	bra		get_battery_voltage3c
	movlw	.25
	movwf	lo
get_battery_voltage3c:
	; 10%
	movlw	LOW  lithium_36v_10
	movwf	sub_a+0
	movlw	HIGH lithium_36v_10
	movwf	sub_a+1
	call	subU16							; sub_c = sub_a - sub_b
	btfsc	neg_flag
	bra		get_battery_voltage3d
	movlw	.10
	movwf	lo
get_battery_voltage3d:
	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_voltage3d			; 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

	btfsc	ambient_sensor
	bra		get_ambient_level1				; normal OSTC3 hardware

	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_max_high_cr		; cR and 2 hardware brightest setting
	dcfsnz	isr1_temp,F
	movlw	ambient_light_max_eco			; brightest setting
	dcfsnz	isr1_temp,F
	movlw	ambient_light_max_medium		; brightest setting

	movff	WREG,ambient_light+0			; set to max.
	movff	ambient_light+0,max_CCPR1L		; store value for dimming in TMR7 interrupt
	return

get_ambient_level1:
	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: divide by 16
	banksel	ambient_light
	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					; YES - 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:
;	movlw	.10
;	subwf	ambient_light+0,F				; subtract 10 (ADC Offset)
;	btfsc	STATUS,N
;	movwf	ambient_light+0					; avoid clipping

	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_cr		; cR and 2 hardware brightest setting
	btfss	battery_gauge_available
	movlw	ambient_light_max_high_15V		; 1.5V battery brightest setting
	btfsc	battery_is_36v					; 3.6V battery in use?
	movlw	ambient_light_max_high_36V		; YES - 3.6V battery brightest setting
	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	ambient_light
	incf	ambient_light+0,F				; +1
	cpfslt	ambient_light+0					; smaller than 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	ambient_light
	cpfsgt	ambient_light+0					; bigger than WREG?
	movwf	ambient_light+0					; NO - set to min
	banksel	common

	movff	ambient_light+0,max_CCPR1L		; store value for dimming in TMR7 interrupt
	return

	global	get_analog_inputs
get_analog_inputs:							; start ADC and wait until finished
	bsf		adc_running						; =1: The ADC is in use
	btfsc	TFT_PWM
	bra		get_analog_inputs				; wait for PWM low
	movlw	b'00100000'						; 2.048V Vref+ -> 1 LSB = 500 µV
	movwf	ADCON1
	movlw	b'00100001'						; power on ADC, select AN8
	rcall	wait_adc
	bcf		STATUS,C
	rrcf	ADRESH,F						; /2
	rrcf	ADRESL,W
											; add to o2_mv_sensor1:2
	addwf	o2_mv_sensor1+0,F
	movf	ADRESH,W
	addwfc	o2_mv_sensor1+1,F
											; divide by 2
	bcf		STATUS,C
	rrcf	o2_mv_sensor1+1,F				; /2
	rrcf	o2_mv_sensor1+0,F

	movlw	HIGH ignore_mv
	cpfsgt	o2_mv_sensor1+1					; > ignore_mv ?
	bra		get_analog_inputs2a				; NO
											; YES - ignore this reading
	clrf	o2_mv_sensor1+1
	clrf	o2_mv_sensor1+0
get_analog_inputs2a:
											; ignore 1.9 mV noise for not-connected inputs
	tstfsz	o2_mv_sensor1+1					; > 25.5mV ?
	bra		get_analog_inputs2				; YES - skip here
	movlw	.19
	cpfsgt	o2_mv_sensor1+0					; > 1.9mV ?
	clrf	o2_mv_sensor1+0					; NO - clear result
get_analog_inputs2:
	movlw	b'00100101'						; power on ADC, select AN9
	rcall	wait_adc
	bcf		STATUS,C
	rrcf	ADRESH,F						; /2
	rrcf	ADRESL,W
											; add to o2_mv_sensor2:2
	addwf	o2_mv_sensor2+0,F
	movf	ADRESH,W
	addwfc	o2_mv_sensor2+1,F
											; divide by 2
	bcf		STATUS,C
	rrcf	o2_mv_sensor2+1,F				; /2
	rrcf	o2_mv_sensor2+0,F

	movlw	HIGH ignore_mv
	cpfsgt	o2_mv_sensor2+1					; > ignore_mv ?
	bra		get_analog_inputs3a				; NO
											; YES - ignore this reading
	clrf	o2_mv_sensor2+1
	clrf	o2_mv_sensor2+0
get_analog_inputs3a:
											; ignore 1.9 mV noise for not-connected inputs
	tstfsz	o2_mv_sensor2+1					; > 25.5 mV ?
	bra		get_analog_inputs3				; YES - skip here
	movlw	.19
	cpfsgt	o2_mv_sensor2+0					; > 1.9 mV ?
	clrf	o2_mv_sensor2+0					; NO - clear result
get_analog_inputs3:
	movlw	b'00101001'						; power on ADC, select AN10
	rcall	wait_adc
	bcf		STATUS,C
	rrcf	ADRESH,F						; /2
	rrcf	ADRESL,W
											; add to o2_mv_sensor3:2
	addwf	o2_mv_sensor3+0,F
	movf	ADRESH,W
	addwfc	o2_mv_sensor3+1,F
											; divide by 2
	bcf		STATUS,C
	rrcf	o2_mv_sensor3+1,F				; /2
	rrcf	o2_mv_sensor3+0,F

	movlw	HIGH ignore_mv
	cpfsgt	o2_mv_sensor3+1					; > ignore_mv ?
	bra		get_analog_inputs4a				; NO
											; YES - ignore this reading
	clrf	o2_mv_sensor3+1
	clrf	o2_mv_sensor3+0
get_analog_inputs4a:
											; ignore 1.9mV noise for not-connected inputs
	tstfsz	o2_mv_sensor3+1					; > 25.5 mV ?
	bra		get_analog_inputs4				; YES - skip here
	movlw	.19
	cpfsgt	o2_mv_sensor3+0					; > 1.9 mV ?
	clrf	o2_mv_sensor3+0					; NO - clear result
get_analog_inputs4:
	bcf		ADCON0,0						; power off ADC
	bcf		adc_running						; =1: the ADC is in use
	return

	global	piezo_config					; set up piezo sensitivity of heinrichs weikamp piezo buttons (~30ms)
piezo_config:								; settings between 20 and 200
	clrf	TMR5H
	clrf	TMR5L							; ~2sec
	bcf		PIR5,TMR5IF						; clear flag
	bcf		switch_right
	bcf		switch_left
piezo_config0:
	btfsc	switch_right
	bra		piezo_config
	btfsc	switch_left
	bra		piezo_config					; restart on button press

	btfss	PIR5,TMR5IF
	bra		piezo_config0					; wait loop

	bcf		INTCON,GIE

	movff	opt_cR_button_right,WREG		; right button
	btfsc	flip_screen						; 180° rotation ?
	movff	opt_cR_button_left,WREG			; YES - left button
	rcall	piezo_config_tx

	movff	opt_cR_button_left,WREG			; left button
	btfsc	flip_screen						; 180° rotation ?
	movff	opt_cR_button_right,WREG		; YES - right button
	rcall	piezo_config_tx

	movlw	.20								; reserved
	rcall	piezo_config_tx
	movlw	.20								; reserved
	rcall	piezo_config_tx

	bsf		INTCON,GIE
	return

piezo_config_tx:							; send one byte
	movwf	lo								; store byte
	movlw	.8
	movwf	hi								; bit counter
	bcf		TX3_PIEZO_CFG					; start bit
	rcall	piezo_config_wait_bit
piezo_config_tx_loop:
	btfss	lo,0							; LSB first
	bcf		TX3_PIEZO_CFG
	btfsc	lo,0							; LSB first
	bsf		TX3_PIEZO_CFG
	rcall	piezo_config_wait_bit
	rrncf	lo,F
	decfsz	hi,F
	bra		piezo_config_tx_loop
	bsf		TX3_PIEZO_CFG					; stop bit
	rcall	piezo_config_wait_bit
	return

piezo_config_wait_bit:
	setf	TMR5H
	movlw	.255-.26 						; 26 x 31,5µs = 819us
	movwf	TMR5L
	bcf		PIR5,TMR5IF						; clear flag
piezo_config_wait_bit3:
	btfss	PIR5,TMR5IF
	bra		piezo_config_wait_bit3			; wait loop
	return

	global	reset_battery_pointer
reset_battery_pointer:						; reset battery pointer 0x07-0x0C and battery_gauge:5
	extern	lt2942_charge_done
	btfsc	battery_gauge_available			; something to reset?
	call	lt2942_charge_done				; YES - reset accumulating registers to 0xFFFF
	goto	reset_battery_internal_only		; and return


	global	get_analog_switches
get_analog_switches:						; start ADC and wait until finished
	btfsc	analog_switches					; does the OSTC have analog switches?
	bra		get_analog_switches2			; YES
											; NO
	bcf		analog_sw1_pressed				; NO  - clear flag for analog switch 1
	bcf		analog_sw2_pressed				;     - clear flag for analog switch 2
	return									;     - done
get_analog_switches2:
	btfsc	adc_running						; ADC in use?
	return									; YES - abort
											; NO
	movlw	b'00001001'						; left justified
	movwf	ADCON2
;	movlw	b'00000000'						; Vref+ = Vdd
	clrf	ADCON1
	movlw	b'00100101'						; power on ADC, select AN9
	rcall	wait_adc
	banksel	analog_counter
	movff	ADRESH,WREG
	addwf	analog_sw2_raw+0
	movlw	.0
	addwfc	analog_sw2_raw+1
	decfsz	analog_counter,F				; continue averaging?
	bra		get_analog_switches2a			; YES
											; NO - done, compute average
	bcf		STATUS,C
	rrcf	analog_sw2_raw+1
	rrcf	analog_sw2_raw+0				; /2
	bcf		STATUS,C
	rrcf	analog_sw2_raw+1
	rrcf	analog_sw2_raw+0				; /4
	bcf		STATUS,C
	rrcf	analog_sw2_raw+1
	rrcf	analog_sw2_raw+0				; /8
	bcf		STATUS,C
	rrcf	analog_sw2_raw+1
	rrcf	analog_sw2_raw+0				; /16
	movff	analog_sw2_raw+0,analog_sw2
	clrf	analog_sw2_raw+1
	clrf	analog_sw2_raw+0				; reset average registers
;	movlw	.16
;	movwf	analog_counter					; only once...
get_analog_switches2a:
	banksel	common
	bcf		analog_sw2_pressed
	movff	opt_cR_button_left,WREG			; 20-100
	bcf		STATUS,C
	rrcf	WREG							; /2 -> 10-50
	bcf		STATUS,C
	rrcf	WREG							; /2 -> 5-25
	decf	WREG,W							; -1
	decf	WREG,W							; -1
	decf	WREG,W							; -1 -> 2-22
	banksel	analog_sw2
	btfss	button_polarity,1				; (1= normal, 0=inverted)
	bra		sw2_inverted
	addwf	analog_sw2,W					; average (~128)
	cpfsgt	ADRESH
	bra		get_analog_sw1
	banksel	common
	bsf		analog_sw2_pressed				; left button normal
	bra		get_analog_sw1
sw2_inverted:
	subwf	analog_sw2,W					; average (~128)
	cpfslt	ADRESH
	bra		get_analog_sw1
	banksel	common
	bsf		analog_sw2_pressed				; left button inverted
get_analog_sw1:
	banksel	common
	movlw	b'00101001'						; power on ADC, select AN10
	rcall	wait_adc
	banksel	analog_counter
	movff	ADRESH,WREG
	addwf	analog_sw1_raw+0
	movlw	.0
	addwfc	analog_sw1_raw+1
	tstfsz	analog_counter					; continue averaging?
	bra		get_analog_switches1a			; YES
											; NO - done, compute average
	bcf		STATUS,C
	rrcf	analog_sw1_raw+1
	rrcf	analog_sw1_raw+0				; /2
	bcf		STATUS,C
	rrcf	analog_sw1_raw+1
	rrcf	analog_sw1_raw+0				; /4
	bcf		STATUS,C
	rrcf	analog_sw1_raw+1
	rrcf	analog_sw1_raw+0				; /8
	bcf		STATUS,C
	rrcf	analog_sw1_raw+1
	rrcf	analog_sw1_raw+0				; /16
	movff	analog_sw1_raw+0,analog_sw1
	clrf	analog_sw1_raw+1
	clrf	analog_sw1_raw+0				; reset average registers
	movlw	.16
	movwf	analog_counter					; only once...
get_analog_switches1a:
	banksel	common
	bcf		analog_sw1_pressed
	movff	opt_cR_button_right,WREG		; 20-100
	bcf		STATUS,C
	rrcf	WREG							; /2 -> 10-50
	bcf		STATUS,C
	rrcf	WREG							; /2 -> 5-25
	decf	WREG,W							; -1
	decf	WREG,W							; -1
	decf	WREG,W							; -1 -> 2-22
	banksel	analog_sw1
	btfss	button_polarity,0				; (1= normal, 0=inverted)
	bra		sw1_inverted
	addwf	analog_sw1,W					; average (~128)
	cpfsgt	ADRESH
	bra		get_analog_sw_done
	banksel	common
	bsf		analog_sw1_pressed				; right button normal
	bra		get_analog_sw_done
sw1_inverted:
	subwf	analog_sw1,W					; average (~128)
	cpfslt	ADRESH
	bra		get_analog_sw_done
	banksel	common
	bsf		analog_sw1_pressed				; right button inverted
get_analog_sw_done:
	banksel	common
	movlw	b'10001101'						; restore to right justified
	movwf	ADCON2
	btfsc	analog_sw1_pressed
	return
	btfsc	analog_sw2_pressed
	return
	setf	TMR1H							; no button pressed, enhance timer1 to overflow quickly
	return

	END