LMX2316TMX/NOPB National Semiconductor, LMX2316TMX/NOPB Datasheet - Page 15

LMX2316TMX/NOPB

Manufacturer Part Number

LMX2316TMX/NOPB

Description

IC FREQ SYNTH 1.2GHZ 16-TSSOP

Manufacturer

National Semiconductor

Series

PLLatinum™r

Type

PLL Frequency Synthesizerr

Datasheet

1.LMX2306TMNOPB.pdf (19 pages)

Specifications of LMX2316TMX/NOPB

Pll

Yes

Input

CMOS

Output

CMOS

Number Of Circuits

Ratio - Input:output

2:1

Differential - Input:output

No/No

Frequency - Max

1.2GHz

Divider/multiplier

Yes/No

Voltage - Supply

2.3 V ~ 5.5 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

16-TSSOP

Frequency-max

1.2GHz

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

*LMX2316TMX
*LMX2316TMX/NOPB
LMX2316TMX

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2.0 Application Information

2.1 DEVICE PROGRAMMING AFTER FIRST APPLYING

Three MICROWIRE programming methods can be used to

change the function latch, R counter latch, and N counter

latch contents with close phase alignment of R and N

counters to minimize lock up time after the cold power up.

2.2 INITIALIZATION SEQUENCE METHOD

Loading the function latch with [C1, C2] = [1, 1] immediately

followed by an R counter load, then an N counter load,

efficiently programs the MICROWIRE. Loading the function

latch with [C1, C2] = [1, 1] programs the same function latch

as a load with [C1, C2] = [0, 1] and additionally provides an

internal reset pulse described below. This program se-

quence insures that the counters are at load point when the

N counter data is latched in and the part will begin counting

in close phase alignment.

The following results from latching the MICROWIRE with an

F latch word, [C1, C2] = [1, 1]:

2.3 CE METHOD

Programming the function latch, R counter latch and N

counter latch while the part is being held in a powerdown

state by CE allows lowest possible power dissipation. After

the MICROWIRE contents have been programmed and the

part is enabled, the R and N counter contents will resume

counting in close phase alignment. Note that after CE tran-

sitions from LOW to HIGH, a duration of 1 µs may be

required for the prescaler bandgap voltage and oscillator

input buffer bias to reach steady state.

CE can be used to power the part up and down by pin control

in order to check for channel activity. The MICROWIRE does

not need to be reprogrammed each time the part is enabled

and disabled as long as it has been programmed at least

once after V

• The function latch contents are loaded.

• An internal pulse resets the R, N, and timeout counters to

• Latching the first N counter data after the initialization

load state conditions and will TRI-STATE the charge

pump. If the function latch is programmed for the syn-

chronous powerdown case; CE = HIGH, F[2] = HIGH,

F[18] = HIGH, this internal pulse triggers powerdown.

Refer to Section 1.3.1 POWERDOWN OPERATION sec-

tion for a synchronous powerdown description. Note that

the prescaler bandgap reference and the oscillator input

buffer are unaffected by the internal reset pulse, allowing

close phase alignment when counting resumes.

word will activate the same internal reset pulse. Succes-

sive N counter data loads without an initialization load will

not trigger the internal reset pulse.

was applied.

2.4 COUNTER RESET METHOD

This MICROWIRE programming method consists of a func-

tion latch load, [C1, C2] = [0, 1], enabling the counter reset

bit, F[1]. The R and N counter latches are then loaded

followed by a final function latch load that disables the

counter reset. This provides the same close phase alignment

as the initialization sequence method with direct control over

the internal reset. Note that counter reset holds the counters

at load point and will TRI-STATE the charge pump, but does

not trigger synchronous powerdown. The counter reset

method requires an extra function latch load compared to the

initialization sequence method.

2.5 DEVICE PROGRAMMING

When

LMX2326, first determine the frequencies and mode of op-

eration desired. Data register is programmed with a 21-bit

data stream shifted into the R counter, N counter, or the F

latch. The Functional Description section shows the bits for

the R counter, and the corresponding information for the N

counter. The FL

FUNCTION AND INITIALIZATION LATCHES section. Typi-

cal numbers for a GSM application example are given. In the

example, the RF output is locking at 950 MHz (f

200 kHz channel spacing (f

reference input is 10 MHz (f

is 32. An example of both methods of FastLock will be

shown.

The last two bits (control bits C1 and C2) of each bit stream

identify which counter or FL

example, to program the R counter, C1 and C2 will be 0,0.

Immediately proceeding these two bits is the N, R, or F bits

providing the divide ratios and FastLock mode information.

For example, to load the N counter, the last two bits C1 and

C2 must be 10.

Once the control bits have been determined, the frequency

information must be determined. To begin, determine the N

and R counter values as follows:

For this example R and N are determined as follows:

programming

Control Bits

N = 950 MHz/200 kHz = 4750

R = 10 MHz/200 kHz = 50

programming information is given in the

N = f

R = f

the

vco

osc

comparison

and

osc

mode will be programmed. For

comparison

LMX2306,

R Counter

N Counter

Function Latch

Initialization

) and the prescaler value (P)

DATA Location

). The crystal oscillator

LMX2316,

www.national.com

vco

) with a

and

LMX2316TMX/NOPB National Semiconductor, LMX2316TMX/NOPB Datasheet - Page 15

LMX2316TMX/NOPB

Specifications of LMX2316TMX/NOPB

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