1. The System Structure for the DAC

Among various DAC topologies, current steering (CS) DAC is the best candidate for high speed applications because it drives resistive load directly without an output buffer. CS DACs are based on an array of matched current sources that are switched to the output. Three different architectures are possible depending on the implementation of this array: binary, unary and segmented. The binary structure is simple and easy to implement, but it has serious glitch, poor linearity, and cannot achieve high resolution. The unary structure requires an additional decoding circuit to convert the input binary code into a thermometer code, and also requires large number of current sources, and its scale increases exponentially with resolution. However, its linearity and monotonicity are good, and the glitch of the output signal will be greatly weakened, also the requirement of the process matching is lower. The segmented structure can balance the performance and the cost. In this design it can be 5+1, 4+2, 3+3, 2+4, 1+5. No matter what combination form, the Integral Nonlinearity (INL) errors are the same ^[7], the Differential Nonlinearity (DNL) error in the segmented architecture can be presented as Eq.(1) with binary-weighted bits (B) and the relative standard deviation of a unit current source ($\sigma(I) / I$).

According to Eq.(1), for the combination form of 5+1, 4+2, 3+3, 2+4, 1+5 the DNL and current numbers are 1.73$\sigma(I) / I$ and 32 signals, 2.64$\sigma(I) / I$ and 17 signals, 3.87$\sigma(I) / I$ and 10 signals, 5.56$\sigma(I) / I$ and 7 signals, 7.94$\sigma(I) / I$ and 6 signals. In this design, to balance performance and complexity, and the DNL performance is taken seriously so finally 4+2 is selected, in which the high 4 bits take the thermometer code while the low 2~bits take the binary code. The block diagram of the system is shown in Fig. 1. Among them, D0\textasciitilde{}D5 are the input digital codes, $\textit{V}$$_{\mathrm{o}}$ and $\textit{V}$$_{\mathrm{on}}$ are output differential analog signals.

The digital part are labelled green in Fig. 1, which includes the input register, the thermometer decoding circuit, the synchronous latch, the switch array and the clock driver circuit. The 6-bit input digital signals are synchronized into the input register under the control of the clock. Through the decoding circuit, the output data are sent to the synchronous latches. Through the processing of the synchronous latch circuit, the timing synchronization and the low crossing point signal are produced, which can be used to control the switch array to select different current sources. The analog part are labelled yellow in Fig. 1, which includes bandgap voltage reference, voltage to current converter and current source array. The bandgap circuit provides an accurate reference voltage, and then the voltage to current conversion circuit converts the reference voltage into a reference current, and the reference current provides a bias to the entire current source through a cascode current mirror to bias the circuit. The design of the key building blocks will be analyzed from the performance perspective.

2. The Current Source Array

Current source array is the most important element in ultra-high speed DAC, and its performance directly affects the static and dynamic performance of the whole DAC system. On top of Fig. 1 is the current source array of the DAC. The design requirements for the current source are: good matching between the current sources and large output impedance.

For the current source, the transistor works in the saturation region, and the current can be expressed as

In Eq.(2), ${\beta}$ is the transconductance parameter, ${μ}$ is the carrier mobility of MOS transistors, $\textit{C}$$_{\mathrm{ox}}$ is the gate oxide capacitance per unit area. W and L are the width and length of the MOS transistor, $\textit{V}$$_{\mathrm{GS}}$ is the gate-source voltage and $\textit{V}$$_{\mathrm{TH}}$ is the threshold voltage. The current deviation can be expressed as

As ${\beta}$ and $\textit{V}$$_{\mathrm{TH}}$ are independent random variable, the matching characteristics of MOS transistors can be expressed by the variance of current,

Here, for convenience of discussion, two parameters of variance are derived.

$\textit{A}$$_{\mathrm{{β}}}$ and $\textit{A}$$_{\mathrm{VTH}}$ are the mismatch parameters of current source for ${\beta}$ and $\textit{V}$$_{\mathrm{TH}}$, respectively.

From Eq. (4-6) we can get

For the matching requirement, a thermometer code n-bit DAC array generally consists of N=2$^{\mathrm{n}}$ identically designed unit current sources, one of them is the dummy, The k$^{\mathrm{th}}$ current can be written as

In the above equations, ${\varepsilon}$$_{\mathrm{k}}$ stands for the error between the k$^{\mathrm{th}}$ current value and the mean value of the current source. $\overline{I}$ is the mean value of the output current. The relation between DAC static performance (DNL, INL) and current source error ^[8] is listed in Eq. (9, 10).

Here X is the digital input code (0{\textless}X{\textless}N). The influence of current source matching error on the SFDR of CS DAC is analyzed ^[9] based on the power spectrum analysis of the current source random matching error, which can be presented in Eq.(11).

${\sigma}$$_{\mathrm{u}}$ is the matching error between the identically designed unit current sources. It can be seen from Eq. (9-11) that the random matching error of the current source directly affects the static and dynamic performance of the CS DAC.

Among the three static indicators of DNL, INL and INL yield, INL yield has the highest requirement for current source mismatch. According to Bosch Model ^[10], the relation between INL Yield and relative deviation can be expressed as

Here, C can be written as

$\mathrm{inv}\_ \text{norm}_{(- x,x)}$ is the inverse function of the normal cumulative function.

Setting the 10 bit accuracy, for INL_Yield equal to 99.7%, the $σI$/I value should be smaller than 0.5%, the mismatch characteristics of MOS transistors are analyzed and deduced according to Eq.(7), and the minimum area of the unit current source needs to be satisfied with Eq.(14):

The minimum area of the unit current source transistor is 16.9 $μm^2$ according to Eq.(14). In this design, the W and L are set to be 18 μm and 1.5 μm.

For the output impedance requirements, we can obtain the influence of current source impedance on the static and dynamic performance of DAC respectively ^[11].

For the static performance,

Here i represent the value of the ith current source, $\rho=R_{\mathrm{L}} / r_{0}$, the load resistance is expressed as $\textit{R}$$_{\mathrm{L}}$, and $\textit{r}$$_{0}$ stands for the output impedance of the unity current source. The influence of output impedance on dynamic performance ^[12] can be obtained in Eq.(17).

From Eq.(17) it can be seen that the SFDR of CS DAC can be improved with the increase of unit current source output impedance while other conditions remain unchanged.

Based on the above analysis, set $\textit{R}$$_{\mathrm{L}}$ equal to 50 ${ω}$ for matching purpose, and if we want the SFDR better than 50 dB, the output resistance should be larger than 15 K${ω}$, here a PMOS cascode circuit is designed, as shown in Fig. 2.

To ensure good matching performance between the current sources and reduce their area, the M1 transistor should be allocated larger overdrive voltage, M2 as the common gate transistor can improve the output impedance of the whole current source. PMOS is chosen to implement the current source for three reasons. 1. The PMOS transistor has a smaller leakage current mismatch compared with its NMOS counterpart; 2.The PMOS transistor is independently produced in the N-well and can effectively isolate the crosstalk and other noise through the substrate; 3.The mobility of the hole is lower than the electron, and the PMOS current source has a lower 1/f noise relative to the NMOS transistors ^[13]. In addition, M2 also plays an isolation role, which can significantly reduce the influence of S point voltage change on the value the current source.

3. The Switch Array

Attentions has to be paid to the following design considerations of the current switch: switch control signal should be synchronized; differential switch cannot turn off at the same time, always ensure the “make before break”; switch on resistance should be as small as possible; switch charge injection and clock feed through effect should be as small as possible; switch source node voltage fluctuation should be small.

According to the requirements of the above analysis, the source degeneration switch is designed in this paper, and the specific circuit is shown in Fig. 3(b). Compared with the traditional differential switch, shown in Fig. 3(a), two normally on dummy transistors are connected at the source end to isolate the source and the output of the current, so that the coupling of the control signal will not affect the S point, nor will the bias point be affected. The switch structure can not only increase the input voltage range of the two switch linear transmission, but also reduce the capacitance of the gate input, thereby reducing the glitch at the output, and improve the dynamic performance of the CS DAC.

For the traditional differential switch, shown in Fig. 3(a), ignoring the subthreshold conducting, if the differential voltage (${δ}$$\textit{V}$$_{\mathrm{in}}$=$\textit{V}$$_{\mathrm{s}}$-$\textit{V}$$_{\mathrm{sn}}$) is larger than $\textit{V}$$_{\mathrm{min1}}$, one transistor is cut off, and all the current $\textit{I}$$_{\mathrm{cs}}$ goes through the other transistor, $\textit{V}$$_{\mathrm{min1}}$can be expressed in Eq.(18)

For the source degradation switch designed, the voltage $\textit{V}$$_{\mathrm{min2}}$ can be expressed in Eq.(19)

Here, $\textit{g}$$_{\mathrm{m }}$is the transconductance of switch transistor (M3, M4 & M9, M10), $\textit{R}$$_{\mathrm{on}}$ stands for the equivalent resistance of degeneration transistor (M7, M8). It is obvious that the source degeneration switch has larger linear range.

For the traditional differential switch, if ${δ}$$\textit{V}$$_{\mathrm{in}}${\textless}{\textbar}$\textit{V}$$_{\mathrm{min1}}${\textbar}, the input capacitance seen from the gate of switch PMOS transistor can be expressed in Eq.(20)

However, for the source degradation switch designed, this value is presented in Eq.(21)

It can be seen that the input capacitance is greatly reduced, so that the clock can work at higher speed.

Fig. 4 compares the DC and transient characteristic of source degeneration switches with the traditional ones by simulation.

Fig. 4(a) shows the DC characteristics, curve 1 is the traditional switch, curve 2 is the source degradation switch. It can be seen that the linear range for the source degeneration switch is significantly greater than the traditional differential switch. The source degeneration switch designed can realize fast switching, thus improving its performance. From the transient characteristic simulation in Fig. 4(b), it can be seen that the source degradation switch (curve 2) has a smaller glitch output than the traditional differential switch (curve 1).

4. The Clock Drive Circuit

The clock synchronization performance and its drive capability will have a great impact on the dynamic performance of CS DAC. Due to the transistors’ gate capacitance and interconnect capacitance, the clock has to drive a large capacitive workload. In addition, the input registers, decoding registers and the synchronization latch after the decoding circuit has certain delay, thus the clock signal which controls the corresponding flip flops and latches must have an equal or larger delay, to ensure the correctness of data conversion. The clock driver circuit designed in this paper is shown in Fig. 5.

As shown in the diagram, the circuit uses the inverter chain structure to produce the clock signals required by each branch of the inverter. The switch K1 and K2 are used to ensure that the delay of the differential clock signals is consistent. The external high-speed clock signal comes into the circuit, buffered by the inverter and become two differential clock signals (n1 and n3, n2 and n4) which control the trigger for input register; after a certain delay, produce the two differential clock signal (n5 and n7, n6 and n8), which control the trigger for Flip-Flops of decoder outputs; single-phase clock signal (n9, n10, n11) control the synchronization latch to work. In the clock drive circuit, in order to enhance the driving ability of the clock, the size of the inverter is increased step by step. To obtain the best time delay and drive capacity, the size of each level should be exponentially the size of its front stage.

The clock jitter has a very important influence on the performance of ultra-high speed DAC, The simulated eye diagram for input signal of 2 GHz is shown in Fig. 6. The signal to noise ratio (SNR) limited by jitter ^[14] is presented in Eq.(22)

where $\textit{f}$$_{\mathrm{sig}}$ is the frequency of a sinusoidal input signal and ${\sigma}$$_{\mathrm{t}}$ is the standard deviation of the sampling clock jitter. For 1 GHz input, if we want the SNR performance better than 4 bit, then the clock jitter should be less than 8.12 ps. It can be seen that the clock jitter of the circuit is 3.92 ps, which meets the design requirements.