Difference between revisions of "Rev200 mods"
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* regarding ECO 2016: | * regarding ECO 2016: | ||
**C2 can be decreased to 0.1uF, 50V - and will be a better high frequency filter as a result. | **C2 can be decreased to 0.1uF, 50V - and will be a better high frequency filter as a result. | ||
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**C19-21 have a maximum working voltage of ~9V. These could be replaced with 16V to 25V devices. | **C19-21 have a maximum working voltage of ~9V. These could be replaced with 16V to 25V devices. | ||
− | |||
**C60 won't exceed ~5V, 1.0u, 16V would be fine. | **C60 won't exceed ~5V, 1.0u, 16V would be fine. | ||
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**C101, C121, C136 = 0.1uF, 50V (same as C2 above) | **C101, C121, C136 = 0.1uF, 50V (same as C2 above) | ||
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**C40, C62 has a 3.3V working voltage. 1.0uF, 16V would be fine | **C40, C62 has a 3.3V working voltage. 1.0uF, 16V would be fine | ||
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* Regarding : ECO 2018 : | * Regarding : ECO 2018 : | ||
** this is an input to the micro and requires no change to the associated input circuitry. | ** this is an input to the micro and requires no change to the associated input circuitry. | ||
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* I don't believe that my ECO #15 was captured. This ECO changes the HALL_C input to a 5V CMOS level output. Thus D10A is removed and some sort of buffer or inverter from the 5V supply is inserted. Probably the Schmitt inverter (1200-000348) would work well for this. | * I don't believe that my ECO #15 was captured. This ECO changes the HALL_C input to a 5V CMOS level output. Thus D10A is removed and some sort of buffer or inverter from the 5V supply is inserted. Probably the Schmitt inverter (1200-000348) would work well for this. | ||
Revision as of 02:30, 6 October 2009
- PF Top Nav; PCB; Hardware; Assembly PFCmdMenu iochan
- PCA : SC/MC 218 FET 217 IMU219 Swiffy Rev200_mods
- PFCMD : SC; MC; PFCMD_PY; Pf_calb_table_py; Virtual spring test; PF1_Code_History; PF EEPROM
- SERIES: S01 S02 S03 wow_left wow_right
Contents
PCB needed Revisions
discussion Mon Oct 5
- regarding ECO 2016:
- C2 can be decreased to 0.1uF, 50V - and will be a better high frequency filter as a result.
- C19-21 have a maximum working voltage of ~9V. These could be replaced with 16V to 25V devices.
- C60 won't exceed ~5V, 1.0u, 16V would be fine.
- C101, C121, C136 = 0.1uF, 50V (same as C2 above)
- C40, C62 has a 3.3V working voltage. 1.0uF, 16V would be fine
- Regarding : ECO 2018 :
- this is an input to the micro and requires no change to the associated input circuitry.
- I don't believe that my ECO #15 was captured. This ECO changes the HALL_C input to a 5V CMOS level output. Thus D10A is removed and some sort of buffer or inverter from the 5V supply is inserted. Probably the Schmitt inverter (1200-000348) would work well for this.
discussion Sun Oct 4
- overall our goal is it keep to a minimum the number of changes. The changes they we have proposed are absolutely necessary from our point of view.
- changing 0.8mm headers to 1mm
- We need to stay with the 12 x 0.8mm header for the pyramid, EC30 MILE, and IMU. Fortunally we need only 1 part number. The 5 position linear spring header can become 1mm
- 4 Channel DAC
- We would like this to remain.
- Primary Li cells
- We would like these to remain. We may wish to locate SMT cells for both primary and 2ndary, and ones that have lower height profile.
- Current sensors :
- We're aware of the linearity issue.
- The present design with the current sensors can actually cause an over-voltage condition on the dsPIC. When this happens there are offset and cross coupling issues on all channels. The slight lose in resolution is minor compared with the upside.
- Hall sensor should remain. The location of the sensor may change slightly.
- The purpose of the connection to TP252 is so that we may experiment with alternative sensors. At present we don't have any.
- IMU
- I believe we would like to stay with the right ankle 12 pin x 0.8mm header. KS would like it moved down a few MM. We need to see the full V2 design to finalize this connector.
- Temperature of coin cells:
- We've monitored the temperature. However, I wasn't aware of the narrow temperature limitation of the cells. Clearly this could be an issue.
FET
- (1) w/clamp circuit - use thermal vias for R4 - this device is impossible to replace
- will try low temp solder and send to MPD
- (2) height of coin cells is too great. need the cells from this original coin cell specification
- (3) pg 4/8 : populate coin cell charger as default
- populate BT2,BT3 as default, DNP BT1,BT4 (but keep R18, D21)
- DNP D13 only if primary coins are installed.
- Would like the coin cells to have 6.0 to 6.1V to be fully changed. ABS maximum is 6.2V
- It doesn't appear to be possible to obtain this tight voltage specification with 1% resistors and the (PDF) MIC5235 LDO. The LDO has up to 2% variation in its output over temperate. Thus a total variation of upto +- 3.65% could be expected.
- 6.2 +- 3.65% = 5.98V to 6.42V
- expect a 150-200mV drop across D13
- (4) change D13 (and D21 ?) to diode that actually has 200mV drop @ 1uA. BAS116-F-7 appears to have 427mV @ 0.3uA
- See : (PDF) - Diodes Inc BAS116-7-F fig 3, pg 2]
- (5) pg 4/8 : ability to measure coin cell voltage without charger enabled? Connect pin 3 of U10 to something like the SFTYSNS_EN, or MTR_EN signal at TP97 or U20B
SCMC
- (6) pg 7/18 : change cutoff freq to ~15Khz for temp circuit (U22) R102=1k, C73=0.01u
- (7) pg 7/18 : remove R232 - 10k for batt_temp_mon pullup
- (8) pg 7/18 : remove R245 - 220 ohm for mtr_temp_mon pullup
- (10) pg 7/18 : R206, R216 -> 6.66k to scale range 0-5V to 0-3.0V (current sensors)
- presently 5V @ current sensor becomes 3.283V, but ADC reference is 3.0V so of the 75.76A range (0->5V), only 69.23A are viable. Thus range is -37.88A to +31.34A. The scale factor is 65536 / (5/.066 * 3/(5*10/15.23)) = 946.6789
- (11) pg 7/18 : bridge current sensor use same values phase U,V
- (12) Pg 8/18 : increase size of resisters (by 10x) for supply voltage measurement (R91, R94, R221, R88). Keep cut off freq the same.
- (13) pg 8/18 : populate so measurement of supply voltage is default (R222, R233 installed). its easier to remove components than to add them.
- (14) pg 3/18 : replace 1.25mm header for EC30 enc/hall w/ 12x0.8mm header
- (15) pg 6/18 : replace HALL_C input with SSI_CLK (CMOS 5V) output.
- Remove D10A
- Insert Schmitt inverter (1200-000348) between MC and R86
- (16)
pg 11/18 : (CB) need to determine the accuracy of the RTC. Seems to be drifting.
- (17) pg 18/18 : Remove LSSGA before TP56
- (18) Connect TP56 to LSSGA connector. needs to protect dsPIC, but no other circuity.
- adjust C95 for 15khz cutoff freq
- (19) pg 14/18 : Connect TP252 to LSSGA connector. Needs to protect dsPIC, but no other circuity.
- (20) 3/18 : LSSGA connector signals:
- AGND
- A3V ref (analog 3.0V reference)
- Various power source options such as Vbat(fused), 5.0V, 3.3V. The reference can't (shouldn't)
- TP56 analog in
- TP252 analog in
- Hall_B input
- locate IMU header for easier access. possibly rot180 - or move 2mm away from edge.
- KS - lower position for V2.
- CB - in V2 appears to be much more space in the shell, no other changes may be needed.
IMU
- probably want to upgrade dual axis IMU
- battery measurement circuit needs to be re-done.