MAX3540(2007) 데이터 시트보기 (PDF) - Maxim Integrated

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MAX3540
(Rev.:2007)

Complete Single-Conversion Television Tuner

Maxim Integrated 

Complete Single-Conversion Television Tuner

Interpolating Tracking Filter Coefficients

The TFS[7:0] and TFP[5:0] bits must be reprogrammed

for each channel frequency to optimize performance.

The optimal settings for each channel can be calculated

from the ROM table data using the equations below.

VHF LO filter:

The nominal full-scale current sunk by the IFOVLD pin

is 300μA. The IFOVLD pin requires a 10kΩ pullup resis-

tor to VCC.

The IF overload detector is calibrated at the factory to

attack at 0.6VP-P at IFOUT1. Upon power-up, the base-

band processor must read OD[2:0] from the ROM table

and store it in the IFVOLD register.

TFS

=

10

⎡

⎣⎢(2.4

+

LS0

64

×

0.6) +

(−8.5 +

LS1 ×

16

2) ×

fRF

×

10

-3

⎤

⎦⎥

TFP = INT

⎡

⎢⎢10

[(1.6

+

LP0

64

× 0.4) +

(−6 +

LP1

16

×

2)

×

fRF

×

10

-3

]

⎤

⎥

⎥

⎣⎢

⎦⎥

Closed-Loop RF Gain Control

Closed-loop RF gain control can be implemented by

connecting the IFOVLD output to the RFAGC input.

Using a 10kΩ pullup resistor on the IFOVLD pin, as

shown in the Typical Application Circuit, results in a

nominal 0.5V to 3V control voltage range.

VHF High filter:

TFS

=

⎡

INT ⎢⎢10

[(2.8

+

HS0 × 0.8)

16

+

(−4.2

+

HS1 ×

16

0.8 ) ×

fRF

×10

-3

]

⎤

⎥

⎥

−

20

⎣⎢

⎦⎥

TFP

=

INT

⎡

⎢⎢10

[(1.6

+

HP0

16

× 0.8)

+

(−1.5

+

HP1

16

×

0.6

)

×

fRF

×

10

-3

]

⎤

⎥

⎥

−

10

⎣⎢

⎦⎥

UHF filter:

TFS

=

INT

⎡

⎢⎢10

[(3

+ US0 )

256

+

(−2.6

+

US1

64

×

0.8 ) × fRF ×

10

-3

]

⎤

⎥

⎥

−

20

⎣⎢

⎦⎥

TFP

=

INT

⎡

⎢⎢10

[(1.6

+

UP0

256

× 0.8) + (−1.4

+

UP1

64

×

0.8

)

×

fRF

×

10

-3

]

⎤

⎥

⎥

− 10

⎣⎢

⎦⎥

Where:

fRF = operating frequency in MHz

TFS = decimal value of the optimal TFS[7:0]

setting (Table 9) for the given operating frequency

TFP = decimal value of the optimal TFP[5:0] setting

(Table 10) for the given operating frequency

LS0, LS1, LP0, LP1, HS0, HS1, HP0, HP1, US0, US1,

UP0, and UP1 = the decimal values of the ROM

table coefficients (Table 16).

IF Overload Detector

The MAX3541 includes a broadband IF overload detec-

tor, which provides an indication of the total power pre-

sent at the RF input. The overload-detector output

voltage is compared to a reference voltage and the dif-

ference is amplified. This error signal drives an open-

collector transistor whose collector is connected to the

IFOVLD pin, causing the IFOVLD pin to sink current.

VCO and VCO Divider Selection

The MAX3540 frequency synthesizer includes three VCOs

and eight VCO sub-bands to guarantee a 2160MHz to

4400MHz VCO frequency range. The frequency synthesiz-

er also features an additional VCO frequency divider,

which must be programmed to either 4, 8, 16, or 32

through the VDIV[1:0] bits in the VCO register based on

the channel being received. Table 5 describes how the

VDIV[1:0] bits should be programmed for each band of

operation.

To ensure PLL, lock the proper VCO and VCO sub-band

for the channel being received, which must be chosen by

iteratively selecting a VCO and VCO sub-band then read-

ing the LD[2:0] bits to determine if the PLL is locked. Any

reading from 001 to 110 indicates the PLL is locked. If

LD[2:0] reads 000, the PLL is unlocked and the selected

VCO is at the bottom of its tuning range; a lower VCO sub-

band must be selected. If LD[2:0] reads 111, the PLL is

unlocked and the selected VCO is at the top of its tuning

range; a higher VCO sub-band must be selected. The

VCO and VCO sub-band settings should be progressively

increased or decreased until the LD[2:0] reading falls in

the 001 to 110 range.

Due to overlap between VCO sub-band frequencies, it is

possible that multiple VCO settings can be used to tune to

the same channel frequency. System performance at a

given channel should be similar between the various pos-

sible VCO settings, so it is sufficient to select the first VCO

and VCO sub-band that provides lock.

Layout Considerations

The MAX3540 EV kit can serve as a guide for PCB layout.

Keep RF signal lines as short as possible to minimize

losses and radiation. Use controlled impedance on all

high-frequency traces. The exposed paddle must be sol-

dered evenly to the board’s ground plane for proper

operation. Use abundant vias beneath the exposed pad-

dle for maximum heat dissipation. Use abundant ground

vias between RF traces to minimize undesired coupling.

______________________________________________________________________________________ 13

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