DSPIC30F1010T-30I/MM Microchip Technology, DSPIC30F1010T-30I/MM Datasheet - Page 6

6KB, Flash, 256bytes-RAM, 30MIPS, 21I/O, 16-bit Family,nanoWatt 28 QFN-S 6x6mm T

DSPIC30F1010T-30I/MM

Manufacturer Part Number

DSPIC30F1010T-30I/MM

Description

6KB, Flash, 256bytes-RAM, 30MIPS, 21I/O, 16-bit Family,nanoWatt 28 QFN-S 6x6mm T

Manufacturer

Microchip Technology

Series

dsPIC™ 30Fr

Datasheets

1.AC164335.pdf (286 pages)

2.DM300023.pdf (22 pages)

3.DM300023.pdf (18 pages)

4.DSPIC30F2011-20ISO.pdf (66 pages)

5.DSPIC30F2011-20IP.pdf (26 pages)

6.DSPIC30F1010-30ISO.pdf (26 pages)

7.DSPIC30F1010-30ISO.pdf (50 pages)

Specifications of DSPIC30F1010T-30I/MM

Core Processor

dsPIC

Core Size

16-Bit

Speed

30 MIPs

Connectivity

I²C, IrDA, LIN, SPI, UART/USART

Peripherals

Brown-out Detect/Reset, POR, PWM, WDT

Number Of I /o

Program Memory Size

6KB (2K x 24)

Program Memory Type

FLASH

Ram Size

256 x 8

Voltage - Supply (vcc/vdd)

3 V ~ 5.5 V

Data Converters

A/D 6x10b

Oscillator Type

Internal

Operating Temperature

-40°C ~ 85°C

Package / Case

28-QFN

Data Bus Width

16 bit

Data Ram Size

256 B

Interface Type

I2C, SPI, UART

Maximum Clock Frequency

30 MHz

Number Of Programmable I/os

Number Of Timers

Maximum Operating Temperature

+ 85 C

Mounting Style

SMD/SMT

3rd Party Development Tools

52713-733, 52714-737, 53276-922, EWDSPIC

Development Tools By Supplier

PG164130, DV164035, DV244005, DV164005, PG164120, DM240002, DM300023, DM330011

Minimum Operating Temperature

- 40 C

On-chip Adc

10 bit, 6 Channel

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With

DM300023 - KIT DEMO DSPICDEM SMPS BUCK

Eeprom Size

Lead Free Status / Rohs Status

Details

Other names

DSPIC30F1010T-30I/MMTR

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dsPIC30F1010/202X

7. Module: PWM Jitter

TABLE 1:

EQUATION 2:

EQUATION 3:

DS80319D-page 6

Speed of Operation

The outputs of the PWM module may exhibit a

jitter proportional to the speed of operation of the

device. The jitter may be observed as a deviation

in the PWM Period, Duty Cycle or Phase, and may

be affected independent of each other. As a result,

the maximum deviation exhibited on the PWM

output pin at 30 MIPS is 8.4 nsec.

The jitter is caused by silicon process variations,

noise on the V

temperature of the dsPIC DSC. However, for a

given set of operating conditions, the maximum

jitter will be the same for all three parameters, and

independent of each other.

Table 1 shows the maximum jitter that may be

exhibited at various operating speeds.

The maximum jitter at any operating speed can be

determined using Equation 2.

Where:

• S is the speed of operation in MIPS.

The maximum percentage error observed on the

PWM output can be calculated using Equation 3.

Where:

• x

Work around

Operate the Power Supply PWM module so that

the percentage error in the parameter of interest

(from Equation 3) is within permissible limits of the

application.

Error (%)

Maximum jitter observed (nsec)

interest (PWM period, Duty Cycle or Phase).

parameter of interest (PWM period, Duty Cycle

or Phase).

observed

programmed

30 MIPS

20 MIPS

15 MIPS

is the observed value of parameter of

is the programmed value of

(

-------------------------------------------------------------- -

programmed

rail and the operating

Maximum Jitter on

–

PWM Output

observed

12.6 nsec

16.8 nsec

8.4 nsec

252

-------- -

S ( )

)

⋅

100

8. Module: ADC Module: Global Software

In order to perform multiple analog-to-digital

conversions using the global software trigger, the

PxRDY bits in the ADSTAT register must be

cleared. The data sheet indicates that the user can

configure the ADC pin pairs to perform a

conversion when the GSWTRG bit in the ADCON

the user must then clear the GSWTRG bit and set

it again to perform another conversion. Contrary to

what the data sheet indicates, this will not initiate

another conversion unless the PxRDY bits are

cleared. Clearing the PxRDY bits automatically

clears the GSWTRG bit.

This only applies to a polling based approach. If an

interrupt based approach is used, the user is

required to clear the PxRDY bits in the ADC

Interrupt Service Routine (ISR).

Work around

The following sequence should be followed to

manually trigger ADC conversions using the

global software trigger (polling based only.)

1. Set the GSWTRG bit in ADCON to initiate a

2. Check the PxRDY bits to determine when the

3. Clear the PxRDY bits. The GSWTRG bit will be

4. Repeat steps 1 to 3 to perform additional

Alternatively, the individual software trigger can be

selected by setting the TRGSRCx<5:0> bits in the

ADCPCx register equal to 0x01. Instead of using

the global software trigger, the individual software

trigger (ADCPCx<SWTRGx>) bits can be used to

trigger a conversion on a given analog pin pair. In

a bit polling approach, the PENDx in the ADCPCx

conversion is completed. In an interrupt based

approach, the PxRDY bits get set when the

conversion is complete. This bit must be cleared in

the ADC Interrupt Service Routine in order to

enable future interrupts.

conversion on channels which have the trigger

source as the global software trigger (via the

TRGSRCx<5:0> bits in the ADCPCx

registers).

conversion(s) is completed.

cleared as a result of this operation.

conversions.

Trigger

DSPIC30F1010T-30I/MM Microchip Technology, DSPIC30F1010T-30I/MM Datasheet - Page 6

DSPIC30F1010T-30I/MM

Specifications of DSPIC30F1010T-30I/MM

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