I2C fast problems

[Tim Bobbins]

I am having I2C speed problems. The trouble is I cannot reach any speed but the slow 100kHz - which is posing a big problem for my current application. I am using the ex_slave.c ccs example file with my PIC877a. For the master side I am using the code below (a copy of the code found elsewhere in this forum). This pic is a 873a. Both PICs use a 20Mhz external crystal.

The communication works perfectly using the FAST=100000 statement. If I alter it even by one, communication halts. Typical values I have tried are 200000, 400000. A buffer chip recommended in this forum has even been inserted with no change.

I am at a loss to explain, much less fix this problem. Can someone please shed some light on this?
I am using CCS compiler 4.032, and reverted back to 3.247 with no success with either.

[Ttelmah]

Big mistake in code as posted, is the #use delay statement...
You have the clock as _2MHz_, not 20MHz.
If the RS232 is working, you need to check your crystal...
At 2MHz, timing will be very borderline on the receive. It typically takes about 30 instructions to arrive in an interrupt handler. Add the handler itself, and for even the simple demo, you can easily be talking in excess of 100 instructions. At 2MHz, 0.2mSec. Using the only I2C clock available (with a 2MHz clock, the hardware can do 500000bps, or 125000bps - I suspect the compiler is selecting the first, as soon as the rate you request goes above 125000). At 500000bps, a byte, only takes 16uSec....

Best Wishes

[Tim Bobbins]

Yup. thanks for that. I am using the '20M' value now so its unmistakable.
That did the trick. Spending too long at looking at the same code over and over sometimes guarantees you dont find the obvious.

[Tim Bobbins]

Although I did get the communications speed running to near 250kHz, anything over would prove unreliable. The goal is to reach the high speed of 450kHz.
Has anyone been successful at doing this?

Once again:
873A-> master 877A -> slave. both operate at 20Mhz
both are connected with a short 1" wire using a 1k pullup (experiemented with a bus driver too)

I am using a 50us delay between writes. No delay results in no communication.

[Ttelmah]

It is important to understand the limitations of the BRG on the MSSP. At 20MHz, the only rates available to you, are:
5MHz
1.25MHz
312.5KHz

Unless you use Timer2.
If you want to go faster than 312KHz, the next 'step', is 1.25Mhz, and if you select this, the chip will give this speed. However if you select rates below this, the fastest it can give you is the 312KHz rate.

Best Wishes

[ckielstra]

[Tim Bobbins]

Thank-you for the responses.

I still am not clear as to why I cannot achieve >250kHz. Now, I can not verify I am getting those speeds, as I do not have a scope to verify. However, the simple test code works at FAST=100000 through FAST=250000. Anything above these it becomes more and more unreliable.

Has anyone been able to achieve the 'high' speed of 400kHz or greater using two PICs to communicate?

Different pull up resistor values have been tried, as well as the LTC1694 chip with no differences.

I am still at a loss.

[Ttelmah]

[PCM programmer]

[GDetienne]

Mister Ckielstra,
could you confirm that the formula is valid for 16F88 and 18F4680 ?
I don't find this information in the data sheet.

Have a nice week end.
Thanks.

[Ttelmah]

Yes, apologies...

This is an example of trying to multi-task, and having a 'leak' between the tasks.... :-(
Unfortunately, I also post on half a dozen private university groups, and I have been suffering for the last fortnight, from trying to get a person there to understand why he cannot have a 1MHz SPI rate, on a 20MHz crystal. He posted a claim, almost exactly like Ckielstra's post, that the divider was available on latter chips for SPI, and I crossed over, and posted here, forgetting this thread was about _I2C_.

I'd guess the the I2C problem is with the pull up's, and bus capacitance. I think PCM programmer will find that the signals, instead of having square edges, have relatively slow rise times.
It is critical to remember that originally I2C, was only specified to 100K. Then 400K was added, and 'ratified' in the 1995 specifications, with the requirement for slope control on the lines being added, and a reduction in the pull up value (for lower line capacitances), or use of a current source being suggested. For example, on a bus with 100pF capacitance, the maximum pull up resistor value, drops from 8KR, to 3K for 400KHz operation. I'd suspect the boards concerned have a capacitance in this region on the lines, and probably 4K7 pull ups.
Going even faster, pushes this area of the spec yet further, and at 1MHz, active pull-ups, or very low resistances, become necessary.

Best Wishes

[Tim Bobbins]

My coworker apparently has tried the same code, but eliminated the FORCE_HW tag in the #use i2c line. He was easily able to ramp up to 450kHz with no difficulties.
I will try it tomorrow myself.
This is mystifying since you'd think the hardware would do a better job that the software bit banging.

[PCM programmer]

The problem is that the software i2c routines can't go that fast. The
actual SCL clock frequency is much less than the specified speed.

For example, I did a test just now with the following #use statement,
with a 16F877 running at 20 MHz. This will generate software i2c code.

[PCM programmer]

I looked at this problem some more.

If you increase the Master PIC's SCL clock frequency beyond about
250 KHz, then byte transactions will finish before the end of the Slave isr.
In the Slave PIC, an SSPIF interrupt occurs at the end of each byte that
is transmitted or received. CCS puts a line of code near the end of the
Slave isr which clears the SSPIF flag. So if a byte finishes before
the end of the isr, it will set the SSPIF flag, but then the flag will be
cleared at the end of the isr. The PIC won't see that next interrupt.

One fix for this is to clear the SSPIF flag at the start of the Slave isr
instead of the end. This can be done by adding the NOCLEAR directive
and by calling clear_interrupt() at the start of the Slave isr. Example:

[Tim Bobbins]

No nooo! I have anything but lost interest in this topic. I am loosing sleep over it as a matter of fact. I've been very busy the past few days, so i havent had time to continue my work, plus I didnt feel I had anything else constructive to contribute just yet.

I do not have the needed equipment to diagnose so I am very appreciative of PCM Programmer to take his time to look into this problem!

That is a wonderful find! I will try it tonight.

Was it the I2C hardware, or software method you tried?